WSPR: RaspberryPi
Revision as of 07:18, 19 April 2016 by Onnowpurbo (talk | contribs) (New page: Raspberry Pi bareback LF/MF/HF/VHF WSPR transmitter Makes a very simple WSPR beacon from your RasberryPi by connecting GPIO port to Antenna (and LPF), operates on LF, MF, HF and VHF bands...)
Raspberry Pi bareback LF/MF/HF/VHF WSPR transmitter
Makes a very simple WSPR beacon from your RasberryPi by connecting GPIO port to Antenna (and LPF), operates on LF, MF, HF and VHF bands from 0 to 250 MHz.
It is now compatible with both the original Raspberry Pi and the Raspberry Pi 2.
Installation / update:
Make sure you are using the latest kernel by updating your system. The latest kernel includes fixes wich improve NTP ppm measurement accuracy: sudo apt-get update sudo apt-get dist-upgrade
Download and compile code: sudo apt-get install git git clone https://github.com/JamesP6000/WsprryPi.git cd WsprryPi make
See the accompanying BUILD file for more details.
Usage: (WSPR --help output):
Usage:
wspr [options] callsign locator tx_pwr_dBm f1 <f2> <f3> ...
OR
wspr [options] --test-tone f
Options:
-h --help
Print out this help screen.
-p --ppm ppm
Known PPM correction to 19.2MHz RPi nominal crystal frequency.
-s --self-calibration
Call ntp_adjtime() before every transmission to obtain the PPM error of the xtal.
-r --repeat
Repeatedly, and in order, transmit on all the specified freqs.
-x --terminate <n>
Terminate after n transmissions have been completed.
-o --offset
Add a random frequency offset to each transmission:
+/- 80 Hz for WSPR
+/- 8 Hz for WSPR-15
-t --test-tone freq
Simply output a test tone and the specified frequency. Only used
for debugging and to verify calibration.
-n --no-delay
Transmit immediately, do not wait for a WSPR TX window. Used
for testing only.
Frequencies can be specified either as an absolute TX carrier frequency, or using one of the following strings. If a string is used, the transmission will happen in the middle of the WSPR region of the selected band. LF LF-15 MF MF-15 160m 160m-15 80m 60m 40m 30m 20m 17m 15m 12m 10m 6m 4m 2m -15 indicates the WSPR-15 region of band .
Transmission gaps can be created by specifying a TX frequency of 0 Note that 'callsign', 'locator', and 'tx_power_dBm' are simply used to fill in the appropriate fields of the WSPR message. Normally, tx_power_dBm should be 10, representing the signal power coming out of the Pi. Set this value appropriately if you are using an external amplifier.
Radio licensing / RF:
In order to transmit legally, a HAM Radio License is REQUIRED for running this experiment. The output is a square wave so a low pass filter is REQUIRED. Connect a low-pass filter (via decoupling C) to GPIO4 (GPCLK0) and Ground pin of your Raspberry Pi, connect an antenna to the LPF. The GPIO4 and GND pins are found on header P1 pin 7 and 9 respectively, the pin closest to P1 label is pin 1 and its 3rd and 4th neighbour is pin 7 and 9 respectively. See this link for pin layout: http://elinux.org/RPi_Low-level_peripherals Examples of low-pass filters can be found here: http://www.gqrp.com/harmonic_filters.pdf
The expected power output is 10mW (+10dBm) in a 50 Ohm load. This looks neglible, but when connected to a simple dipole antenna this may result in reception reports ranging up to several thousands of kilometers.
As the Raspberry Pi does not attenuate ripple and noise components from the 5V USB power supply, it is RECOMMENDED to use a regulated supply that has sufficient ripple supression. Supply ripple might be seen as mixing products products centered around the transmit carrier typically at 100/120Hz.
DO NOT expose GPIO4 to voltages or currents that are above the specified Absolute Maximum limits. GPIO4 outputs a digital clock in 3V3 logic, with a maximum current of 16mA. As there is no current protection available and a DC component of 1.6V, DO NOT short-circuit or place a resistive (dummy) load straight on the GPIO4 pin, as it may draw too much current. Instead, use a decoupling capacitor to remove DC component when connecting the output dummy loads, transformers, antennas, etc. DO NOT expose GPIO4 to electro- static voltages or voltages exceeding the 0 to 3.3V logic range; connecting an antenna directly to GPIO4 may damage your RPi due to transient voltages such as lightning or static buildup as well as RF from other transmitters operating into nearby antennas. Therefore it is RECOMMENDED to add some form of isolation, e.g. by using a RF transformer, a simple buffer/driver/PA stage, two schottky small signal diodes back to back.
TX Timing:
This software is using system time to determine the start of WSPR transmissions, so keep the system time synchronised within 1sec precision, i.e. use NTP network time synchronisation or set time manually with date command. A WSPR broadcast starts on an even minute and takes 2 minutes for WSPR-2 or starts at :00,:15,:30,:45 and takes 15 minutes for WSPR-15. It contains a callsign, 4-digit Maidenhead square locator and transmission power. Reception reports can be viewed on Weak Signal Propagation Reporter Network at: http://wsprnet.org/drupal/wsprnet/spots
Calibration:
Frequency calibration is REQUIRED to ensure that the WSPR-2 transmission occurs within the narrow 200 Hz band. The reference crystal on your RPi might have an frequency error (which in addition is temp. dependent -1.3Hz/degC @10MHz). To calibrate, the frequency might be manually corrected on the command line or a PPM correction could be specified on the command line.
NTP calibration: NTP automatically tracks and calculates a PPM frequency correction. If you are running NTP on your Pi, you can use the --self-calibration option to have this program querry NTP for the latest frequency correction before each WSPR transmission. Some residual frequency error may still be present due to delays in the NTP measurement loop and this method works best if your Pi has been on for a long time, the crystal's temperature has stabilized, and the NTP control loop has converged.
AM calibration: A practical way to calibrate is to tune the transmitter on the same frequency of a medium wave AM broadcast station; keep tuning until zero beat (the constant audio tone disappears when the transmitter is exactly on the same frequency as the broadcast station), and determine the frequency difference with the broadcast station. This is the frequency error that can be applied for correction while tuning on a WSPR frequency.
Suppose your local AM radio station is at 780kHz. Use the --test-tone option to produce different tones around 780kHz (eg 780100 Hz) until you can successfully zero beat the AM station. If the zero beat tone specified on the command line is F, calculate the PPM correction required as: ppm=(F/780000-1)*1e6 In the future, specify this value as the argument to the --ppm option on the comman line. You can verify that the ppm value has been set correction by specifying --test-tone 780000 --ppm <ppm> on the command line and confirming that the Pi is still zero beating the AM station.
PWM Peripheral:
The code uses the RPi PWM peripheral to time the frequency transitions of the output clock. This peripheral is also used by the RPi sound system and hence any sound events that occur during a WSPR transmission will interfere with WSPR transmissions. Sound can be permanently disabled by editing /etc/modules and commenting out the snd-bcm2835 device.
Example usage:
Brief help screen ./wspr --help
Transmit a constant test tone at 780 kHz. sudo ./wspr --test-tone 780e3
Using callsign N9NNN, locator EM10, and TX power 33 dBm, transmit a single WSPR transmission on the 20m band using NTP based frequency offset calibration. sudo ./wspr --self-calibration N9NNN EM10 33 20m
Transmit a WSPR transmission slightly off-center on 30m every 10 minutes for a total of 7 transmissions, and using a fixed PPM correction value. sudo sudo ./wspr --repeat --terminate 7 --ppm 43.17 N9NNN EM10 33 10140210 0 0 0 0
Transmit repeatedly on 40m, use NTP based frequency offset calibration, and add a random frequency offset to each transmission to minimize collisions with other transmissions. sudo ./wspr --repeat --offset --self-calibration N9NNN EM10 33 40m
Usage:
sudo ./wspr <[prefix]/callsign[/suffix]> <locator> <power in dBm> [<frequency in Hz> ...]
e.g.: sudo ./wspr PA/K1JT JO21 10 7040074 0 0 10140174 0 0
where 0 frequency represents a interval for which TX is disabled,
wspr-2 or wspr-15 mode selection based on specified frequency.
WSPR is used on the following frequencies (local restriction may apply):
LF 137400 - 137600
137600 - 137625 (WSPR-15)
MF 475600 - 475800
475800 - 475825 (WSPR-15)
160m 1838000 - 1838200
1838200 - 1838225 (WSPR-15)
80m 3594000 - 3594200
60m 5288600 - 5288800
40m 7040000 - 7040200
30m 10140100 - 10140300
20m 14097000 - 14097200
17m 18106000 - 18106200
15m 21096000 - 21096200
12m 24926000 - 24926200
10m 28126000 - 28126200
6m 50294400 - 50294600
4m 70092400 - 70092600
2m 144490400 -144490600
Reference documentation:
http://www.raspberrypi.org/wp-content/uploads/2012/02/BCM2835-ARM-Peripherals.pdf http://www.scribd.com/doc/127599939/BCM2835-Audio-clocks http://www.scribd.com/doc/101830961/GPIO-Pads-Control2 https://github.com/mgottschlag/vctools/blob/master/vcdb/cm.yaml https://www.kernel.org/doc/Documentation/vm/pagemap.txt
Credits:
Credits goes to Oliver Mattos and Oskar Weigl who implemented PiFM [1] based on the idea of exploiting RPi DPLL as FM transmitter.
Dan MD1CLV combined this effort with WSPR encoding algorithm from F8CHK, resulting in WsprryPi a WSPR beacon for LF and MF bands.
Guido PE1NNZ <pe1nnz@amsat.org> extended this effort with DMA based PWM modulation of fractional divider that was part of PiFM, allowing to operate the WSPR beacon also on HF and VHF bands. In addition time-synchronisation and double amount of power output was implemented.
James Peroulas <james@peroulas.com> added several command line options, a makefile, improved frequency generation precision so as to be able to precisely generate a tone at a fraction of a Hz, and added a self calibration feature where the code attempts to derrive frequency calibration information from an installed NTP deamon. Furthermore, the TX length of the WSPR symbols is more precise and does not vary based on system load or PWM clock frequency.