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README.md
uSDX: micro Software Defined Transceiver
uSDX is a simple and experimental (Class-E driven) SSB and CW SDR transceiver. It can be used to make QRP SSB contacts, or (in combination with a PC) used for the digital modes such as FT8, JS8, FT4. It can be fully-continuous tuned through bands 80m-10m in the LSB/USB-modes with a 2400Hz bandwidth has up to 5W PEP SSB output and features a software-based full Break-In VOX for fast RX/TX switching in voice and digital operations.
The SSB transmit-stage is implemented entirely in digital and software-based manner: at the heart the ATMEGA328P is sampling the input-audio and reconstructing a SSB-signal by controlling the SI5351 PLL phase (through tiny frequency changes over 800kbit/s I2C) and controlling the PA Power (through PWM on the key-shaping circuit). In this way a highly power-efficient class-E driven SSB-signal can be realized; a PWM driven class-E design keeps the SSB transceiver simple, tiny, cool, power-efficient and low-cost (ie. no need for power-inefficient and complex linear amplifier with bulky heat-sink as often is seen in SSB transceivers).
For the receiver, most parts are implemented in digital manner (software): the ATMEGA328P is implementing a 90 degree phase shift circuit, the (CW/SSB) filter circuit and the audio amplifier circuit (now a class-D amplifier). This has simplifies the uSDX circuit a lot, and there are a number of advantages and features (compared to an analog approach): there is no longer a need for an I/Q alignment procedure due to the very accurate 90 degree Hilbert phase shifter; and there are now adjustable IF DSP filters for CW and SSB; and there is an AGC and there is a noise-reducing DSP signal conditioning function and there are three indepent built-in attenuators in the analog front-end which helps utilizing the full dynamic range. The speaker is directly connected and driven by the ATMEGA. A digital mixer with narrow low-pass window (2 kHz), steep roll-off (-45dB/decade) combined with an oversampling and decimating ADC are responsible for a processing gain, dynamic range and alias rejection sufficient to handle weak and strong signal conditions (e.g. contests or listening on 40m just next to broadcasting band).
This experiment is created to try out what is can be achieved with minimal hardware while moving complexity towards software; here the approach followed is to simplify the design where possible while keep a reasonable performance. The result is a cheap, easy to build, versatile QRP SSB transceiver that actually is quite suitable for making QSOs (even in contest situations), however due to the experimental nature some parts are still in progress and hence limited. Feel free to try it out or to experiment with this sketch, let me know your thoughts or contribute here: https://github.com/threeme3/usdx
Note: there is an active online forum discussing the uSDX here: uSDX Forum.
73, Guido pe1nnz@qsl.net
List of features:
- Simple, fun and versatile QRP SSB HF transceiver with embedded DSP and SDR functions;
- EER Class-E driven SSB transmit-stage
- Approximately 5W PEP SSB output from 13.8V supply
- All-Mode support: USB, LSB, CW, AM, FM
- DSP filters: 4000, 2500, 1700, 500, 200, 100, 50 Hz passband
- DSP features: Automatic Gain Control (AGC), Noise-reduction (NR), Voice-triggered Xmit (VOX), RX Attentuators (ATT), TX noise gate, TX drive control, Volume control, dBm/S-meter.
- SSB opposite side-band/carrier supression Transmit: better than -45dBc, IMD3 (two-tone) -33dBc, Receive: better than -50dBc
- Multiband support, continuously tunable through bands 160m-10m (and from 20kHz..99MHz with loss in performance)
- Open source firmware, built with Arduino IDE; allows experimentation, new features can be added, contributions can be shared via Github, software-complexity: 2000 lines of code
- Software-based VOX that can be used as fast Full Break-In (QSK and semi-QSK operation) or assist in RX/TX switching for operating digital modes (no CAT or PTT interface required), external PTT output/PA control with TX-delay
- Simple hardware design with only 4 ICs, a micro-controller and few transistors/passives
- Lightweight and low-cost transceiver design: because of the EER-transmitter class-E stage it is highly power-efficient (no bulky heatsinks required), and has a simple design (no complex balanced linear power amplifier required)
- Fully digital and software-based SSB transmit-stage: samples microphone-input and reconstruct a SSB-signal by controlling the phase of the SI5351 PLL (through tiny frequency changes over 800kbits/s I2C) and the amplitude of the PA (through PWM of the PA key-shaping circuit)
- Fully digital and software-based SDR receiver-stages (optionally): samples I/Q (complex) signal from Quadrature Sampling Detector digital mixer, and performs a 90-degree phase-shift mathematically in software (Hilbert-transform) and cancels out one side-band by adding them
- Three independent switchable analog front-end receiver attenuators (0dB, -13dB, -20dB, -33dB, -53dB, -60dB, -73dB)
- Receiver Noise floor MDS: –135 dBm at 28MHz (in 200Hz BW)
- Receiver Front-end selectivity: steep -45dB/decade roll-off +/-2kHz from tuned-frequency
- Blocking dynamic range: 20kHz offset 123dB, 2kHz offset 78dB
- CW decoder, Straight/Iambic-A/B keyer
- VFO A/B + RIT and Split, and corresponding relay band-filter switching via I2C
- CAT support (TS480 subset), possibility to stream audio, keys, display-text over CAT
- Optional SWR/Power measurement and PA efficiency/overload control
- Battery voltage indicator
- Probably the most cost effective and easy to build standalone SDR/SSB transceiver that you can find. Very much simplified circuit and versatile in use.
Revision History:
Rev. | Date | Features |
---|---|---|
latest | 2021-10-23 | Features for final version. |
R1.02w | 2021-08-23 | TX quality improvements, better robustness against RFI feedback, fix VOX issue, single encoder/button-only control option, 16MHz Arduino Uno/Nano support, CW Messages. Key click reduction, TX bandwidth control, OLED fixes, CAT remote control features including RX audio streaming. CW support, TS480 CAT support, RX quality improvments, semi-QSK, PA PTT out with TX-delay, VFO-A/B/RIT, LPF switching, backlight saving, 160m. |
R1.02j | 2020-10-10 | Integrated SDR receiver, CW decoder, DSP filters, AGC, NR, ATT, experimental modes CW, AM, FM, quick menu, persistent settings, improved SSB TX quality. LCD fix, selectable CW pitch. |
R1.01d | 2019-05-05 | Q6 now digitally switched (remove C31) - improving stability and IMD. Improved signal processing, audio quality, increased bandwidth, cosmetic changes and reduced RF feedback, reduced s-meter RFI, S-meter readings, self-test on startup. Receiver I/Q calibration, (experimental) amplitude pre-distortion and calibration. |
R1.00 | 2019-01-29 | Initial release of SSB transceiver prototype. |
Schematic:
Hardware:
There are many uSDX constructions possible, here are a few common implementations:
- uSDX Sandwich by Manuel, DL2MAN;
- uSDX Transceiver by Barbaros Asuroglu, WB2CBA;
- other designs are announced in the uSDX Forum or can be googled (keywords: uSDX transceiver)
Partially assembled PCB kits can be obtained from various sources:
- Sunil (VU3SUA), with shop: https://inkits.in , providing kits in India;
- Ondra (OK1CDJ) and XYL Alexandra (OK1RS) with shop: https://www.hamshop.cz ;
- via group buys in the uSDX Forum
This project originally started as a QCX modification:
- QCX Mini with uSDX daughterboard with uSDX daughter board;
- QCX+ modification by Mike Dunstan, G8GYW
- QCX-SSB mod for the old QCX.
Firmware: download hex file and do the firmware upload (see also note 1). Use default Arduino Uno fuses (by selecting burn bootloader) and use default CPU clock (16MHz) in case you burn from source code in Arduino IDE.
Operation:
Currently, the following functions have been assigned to shortcut buttons (L=left, E=encoder, R=right) and menu-items:
Menu Item | Function | Button |
---|---|---|
1.1 Volume | Audio level (0..16) & power-off/on (turn left) | E +turn |
1.2 Mode | Modulation (LSB, USB, CW, AM, FM) | R |
1.3 Filter BW | Audio passband (Full, 300..3000, 300..2400, 300..1800, 500, 200, 100, 50 Hz), this also controls the SSB TX BW. | R double |
1.4 Band | Band-switch to pre-defined CW/FT8 freqs (80,60,40,30,20,17,15,12,10,6m) | E double |
1.5 Tuning Rate | Tuning step size 10M, 1M, 0.5M, 100k, 10k, 1k, 0.5k, 100, 10, 1 | E or E long |
1.6 VFO Mode | Selects different VFO, or RX/TX split-VFO (A, B, Split) | 2x R long |
1.7 RIT | RX in transit (ON, OFF) | R long |
1.8 AGC | Automatic Gain Control (ON, OFF) | |
1.9 NR | Noise-reduction level (0-8), load-pass & smooth | |
1.10 ATT | Analog Attenuator (0, -13, -20, -33, -40, -53, -60, -73 dB) | |
1.11 ATT2 | Digital Attenuator in CIC-stage (0-16) in steps of 6dB | |
1.12 S-meter | Type of S-Meter (OFF, dBm, S, S-bar) | |
2.1 CW Decoder | Enable/disable CW Decoder (ON, OFF) | |
2.2 CW Tone | CW Filter+Side-tone (600, 700) | |
2.4 Semi QSK | On TX silents RX on CW sign and word spaces | |
2.5 Keyer speed | CW Keyer speed in Paris-WPM (1..35) | |
2.6 Keyer mode | Type of keyer (Iambic-A, -B, Straight) | |
2.7 Keyer swap | to swap keyer DIH, DAH inputs (ON, OFF) | |
2.8 Practice | to disable TX for practice purposes (ON, OFF) | |
3.1 VOX | Voice Operated Xmit (ON, OFF) | |
3.2 Noise Gate | Audio threshold for SSB TX and VOX (0-255) | |
3.3 TX Drive | Transmit audio gain (0-8) in steps of 6dB, 8=constant amplitude for SSB | |
3.4 TX Delay | Delays TX to allow PA relay to be fully switched on before TX (0-255 ms) | |
3.5 MOX | Monitor on Xmit (audio unmuted during transmit) | |
4.1 CQ Interval | Idle time in seconds before new CQ Message is given (0-60) | |
4.2 CQ Message | CQ Message text, pressing left-button in menu will start sending | L |
8.1 PA Bias min | PA amplitude PWM level (0-255) for representing 0% RF output | |
8.2 PA Bias max | PA amplitude PWM level (0-255) for representing 100% RF output | |
8.3 Ref freq | Actual si5351 crystal frequency, used for frequency-calibration | |
8.4 IQ Phase | RX I/Q phase offset in degrees (0..180 degrees) | |
10.1 Backlight | Display backlight (ON, OFF) | |
power-up | Reset to factory settings | E long |
main | Tune frequency (20kHz..99MHz) | turn |
main | Quick menu | L +turn |
main | Menu enter | L |
RIT | RIT back | R |
menu | Menu back | R |
Operating Instructions:
Tuning can be done by turning the rotary encoder. Its step size can be decreased or increased by a short or long press. A change of band can be done with a double press. The mode of operation is altered with a short press on the right button; a double press on right button narrows the receiver filter bandwidth, the bandwidth is reset every time mode is changed. The volume is changed by turning the rotary encoder while pressed.
There is a menu available that can be accessed by a short left press. With the encoder it is possible to navigate through this menu. When you want to change a menu parameter, a press with left button allows you to change the parameter with the encoder. With the right button it is possible to exit the menu any time. A fast access to the menu and parameter can be achieved by pressing the left button while turning the encoder, once you lift the left button you can immediately change the parameter by turning the encoder.
For receive, by default an AGC is enabled. This increases the volume when there are weak signals and decreases for strong signals. This is good for SSB signals but can be annoying for CW operation. The AGC can be turned off in the menu, this makes the receiver less noisy but require more manual volume change. To further reduce the noise, a noise-reduction function can be enabled in the menu with the NR parameter. To use the available dynamic range optimally, you can attenuate incoming signal by enabling a front-end attenuator with "ATT" parameter. Especially on frequencies 3.5-7 MHz the atmospheric noise levels are much higher, so you can increase the receiver performance by adding attenuation (e.g 13dB) such that the noise-floor is still audible. To calibrate the transceiver frequency, you can tune to a calibrated signal source (e.g. WWV on 10 MHz) and zero-beat the signal by changing "Ref freq" parameter; alternatively you can measure the XTal frequency with a counter and set the parameter. A S-meter of choice (dBm, S, S-bar) can be selected with the S-meter parameter. Selecting an S-bar, shows a signal-strength bar where each tick represents a S-point (6dB).
For SSB voice operation, connect a microphone to the paddle jack, a PTT or onboard "key" press will bring the trasnceiver into transmit. With the "TX Drive" parameter, it is possible to set the mdulation depth or PA drive, it is default set to 4 increasing it gives a bit more punch (compression for SSB). Setting it to a value 8 in SSB means that the SSB modulation is transmitted with a constant amplitude (possibly reducing RFI but at the cost of audio quality). To monitor your own modulation, you can temporarily increase MOX parameter. Setting menu item "VOX" to ON, enters the transceiver in Voice-On-Xmit operation (in TX mode as soon audio is detected), the VOX sensitivity can be configured in the menu with "VOX threshold" parameter. The PA Bias min and max parameters sets the working range of the PWM envelope signal, a range of 0-255 is the full range which is fine if you use a key-shaping circuit for envelope control, but when you directly bias the PA MOSFETs (note 3) with the PWM signal then you specifiy the optimal working range from just above the MOSFET threshold level to the maximum peak power you would like to use (0-180 are good values on my uSDX).
For FT8 (and any other digital) operation, select one of the pre-programmed FT8 bands by double press the rotary encoder, connect the headphone jack to sound card microphone jack, sound card speaker jack to microphone jack, and give a long press on right button to enter VOX mode. Adjust the volume to a minimum and start your favorite FT8 application (JTDX for instance). The sensitivity of the VOX can be set in the "VOX threshold" parameter.
On startup, the transceiver is performing a self-test (when DIAG option is enabled). It is checking the supply and bias voltages, I2C communications and algorithmic performance. In case of deviations, the display will report an error during startup. It also discovers the capabilties of the transceiver depending on the mods made.
Technical Description:
Below the block diagram of the uSDX transceiver:
For SSB reception, the a digital SDR phasing stage is used; this means that a Tayloe Quadrature Samplimg detector supplies individual I and Q outputs, directly fed into the ATMEGA328P ADC inputs for signal processing. The ATMEGA328P (over-)samples the ADC input at a 62kHz sample-rate, an decimates this high-samplerate to a lower samplerate, performs a phase-shift by means of a Hilbert-transform, summing the result to obtain side-band rejection; it subsequently applies a low-pass filtering, AGC and noise-reduction functions. The ADC inputs are low-pass filtered (-40dB/decade roll-off at 1.5kHz cut-off) to prevent aliasing and input are biased with a 1.1V analog reference voltage to obtain additional sensitivity and dynamic range. With the 10-bit ADCs and a 4x over-sampling rate, a theoretical dynamic range of 72dB can be obtained in 2.4kHz SSB bandwidth. LSB/USB mode switching is done by changing the 90 degree phase shift on the CLK0/CLK1 signals of the SI5351 PLL. Three embedded attenuators are available for optimally using dynamic range; the first attenuator is the RX MOSFET switch Q5 responsible for 20dB attenuation, the second attenuator is ADC range (1.1V or 5V) selected by the ATMEGA ADC analog reference (AREF) logic and is responsible for 13dB attenation, the third attenuator is a pull-down of an analog input on the ATMEGA with a GPIO port responsible for 53dB attenation. Combining the three attenuators provides the attenation steps 0dB, -13dB, -20dB, -33dB, -53dB, -60dB, -73dB.
For SSB transmission the uSDX is using a dedicated ADC input as audio-input. An electret-microphone (with PTT switch) is combined with the Paddle jack input, whereby the DOT input acts as the PTT and the DASH input acts as the audio-input. The electret microphone is biased with 5V through a 10K resistor. A 10nF blocking capacitor prevents RF leakage into the circuit. The audio is fed into ADC2 input of the ATMEGA328P microprocessor through a 220nF decoupling capacitor. The ADC2 input is biased at 0.55V via a divider network of 10K to a 1.1V analog reference voltage, with 10-bits ADC resolution this means the microphone-input sensitivity is about 1mV (1.1V/1024) which is just sufficient to process unamplified speech.
uSDX firmware is uploaded to the ATMEGA328P, and facilitates a digital SSB generation technique in a completely software-based manner. A DSP algorithm samples the ADC2 audio-input at a rate of 4x4800 samples/s, performs a Hilbert transformation and determines the phase and amplitude of the complex-signal; the phase-changes are restrictednote 2 and transformed into either positive (for USB) or negative (for LSB) phase changes which in turn transformed into temporary frequency changes which are sent 4800 times per second over 800kbit/s I2C towards the SI5351 PLL. This result in phase changes on the SSB carrier signal and delivers a SSB-signal with a bandwidth of 2400 Hz whereby spurious in the opposite side-band components is attenuated.
The amplitude of the complex-signal controls the supply-voltage of the PA, and thus the envelope of the SSB-signal. The key-shaping circuit is controlled with a 32kHz PWM signal, which can control the PA voltage from 0 to about 12V in 256 steps, providing a dynamic range of (log2(256) * 6 =) 48dB in the SSB signal. C31 is removed to ensure that Q6 is operating as a digital switch, this improves the efficiency, thermal stability, linearity, dynamic range and response-time. Though the amplitude information is not mandatory to make a SSB signal intelligable, adding amplitude information improves quality. The complex-amplitude is also used in VOX-mode to determine when RX and TX transitions are supposed to be made. Instead of using a key-shaping circuit for evelope control, it is possible to directly bias the PA MOSFETs with the (filtered) PWM signal. This has the advantage of less losses and simplifies at the cost of linearity which result in more compression for an SSB signal (which is actually a good thing).
The IMD performance is related dependent on the quality of the system: the linearity (accuracy) of the amplitude and phase response and the precision (dynamic range) of these quantities. Especially the DSP bit-width, the precision used in the DSP algorithms, the PWM and key-shaping circuit that supplies the PA and the PA phase response are critical. Decreasing (or removing) C32 improves the IMD characteristics but at the cost of an increase of PWM products around the carrier.
Results
Here is a sample me calling CQ on 40m with my uSDX at 5W and received back by the Hack Green websdr about 400km away, note that the audio quality has further improved since then.
Several OMs reported a successful QRP DX contacts.
Measurements: The following performance measurements were made, a modified RTL-SDR, Spektrum-SVmod-v0.19, Sweex 5.0 USB Audio device and Audicity player. It is recognized that this measurement setup has its own limitations, hence the dynamic range of the measurements is somewhat limited by the RTL-SDR as this device goes easily into overload. Measurements were made with the following setttings: USB modulation, no pre-distortion, two-tone input 1000Hz/1200Hz where audio level is set just before the point where compression starts. Results:
- Intermodulation distortion products (two-tone; SSB with varying envelope) IMD3, IMD5, IMD7: respectively -33dBc; -36dBc; -39dBc
- Intermodulation distortion products (two-tone; SSB with constant envelope) IMD3, IMD5, IMD7: respectively -16dBc; -16dBc; -19dBc
- Opposite side-band rejection (two-tone): better than -45dBc
- Carrier rejection (two-tone): better than -45dBc
- Wide-band spurious (two-tone): better than -45dBc
- 3dB bandwidth (sweep): 0..2400Hz
Notes:
- AVRDudess tool or avrdude CLI (avrdude -c avrisp -b 19200 -P /dev/ttyACM0 (or: /dev/ttyUSB0) -p m328p -e -U efuse:w:0xFD:m -U hfuse:w:0xD6:m -U lfuse:w:0xFF:m -U flash:w:R1.0x.hex) can be used for uploading the firmware via the ISP connector on the uSDX. Follow Arduino as ISP instructions if you have a Arduino UNO board available (tip: use female-to-male breadboard cables to connect Arduino to uSDX ISP jumper); or USBasp instructions if you have a USBasp programmer, alternatively use USPasp ExtremeBurner; but many other ISP programmers can be used in similar manner such as USBtiny or AVRisp mkII. During ISP, mic should be disconnected, power supply should be connected; in tool do not erase, program EEPROM or set fuse settings (they are by default ok: E=FD H=D6 L=FF).
- Alternatively, in case you have an ATMEGA328P chip with Arduino bootloader, you can place the chip in an Arduino UNO board and upload directly (without the need for a ISP cable and uSDX) by specifying 'arduino' programmer and baudrate 115200.
- Alternatively, in case you have an Arduino 1.8.10 (or newer) environment installed, you can upload the uSDX Sketch directly from the Arduino environment (without using AVRDudess and firmware file); make sure "Tools > Board > Arduino/Genuino Uno", "Tools > Port > /dev/ttyUSB0 or ttyACM0", and then "Sketch > Upload" is selected, while the ATMEGA328P chip is placed in the Arduino UNO socket. It is also possible to use Arduino as ISP method: upload this variation of ArduinoISP to the Arduino board and select "Tools > Programmer > Arduino as ISP", and "Sketch > Upload Using Programmer".
- The occupied SSB bandwidth can be further reduced by restricting the maximum phase change (set MAX_DP to half a unit-circle _UA/2 (equivalent to 180 degrees)). Audio-input can be attenuated by increasing parameter MIC_ATTEN (6dB per step).
- Alternatively, the PA MOSFETs can be directly biased by the PWM envelope signal, basically making the key-shaping circuit redundant. To do so, Q6,Q4,R41,R42,C32,C31 can be removed entirely, whereby C-E pads of Q6 are wired, and where a 10nF capacitor is inserted at IC3A-pin3 and G of Q1-3, and where a 10k resistor is placed at G-D pads of Q4, a 10nF capacitor between S-D pads of Q4, and where a 10k resistor is placed between D of Q4 and G of Q1-3.
Credits:
The uSDX was originally announced in the QRPLabs Forum as a SSB modification for a QCX: QCX is a QRP Labs CW Xcvr kit designed by Hans Summers (G0UPL), originally built for RSGB's YOTA summer camp 2017, a high performance, image rejecting DC transceiver; it is basically a simplified implementation of the NorCal 2030 by Dan Tayloe (N7VE) designed in 2004 combined with a Hi-Per-Mite Active Audio CW Filter by David Cripe (NMØS), Low Pass Filters from Ed (W3NQN) 1983 Articles, a key-shaping circuit by Donald Huff (W6JL), a BS170 switched CMOS driven MOSFET PA architecture as used in the ATS designs by Steven Weber (KD1JV) (originating from the Power MOSFET revolution in the mid 70s), a Ghetto-class-E filter-network published by Paul Harden (NA5N) and an Atmel ATMEGA328P microprocessor, a Hitachi HD44780 LCD display and a Silicon Labs SI5351 Clock Generator (and using a phase shift in the SI5351 clocks).
The uSDX transmitter and receiver stage both running on a ATMEGA328P, including its multiband front-end and direct PA biasing/envelope-generation technique; its concept, circuit, code are a design by Guido (PE1NNZ); the software-based SSB transmit stage is a derivate of earlier experiments with a digital SSB generation technique on a Raspberry Pi. The uSDX sandwitch PCB and class-E LPF design, is the work of Manuel (DL2MAN). Many thanks to all of you who got interested in this project and took the challege and effort to try out and further develop the uSDX; without your valuable feedback and contributions the project could not have kept moving on, improving and challenging new ideas!