2298 lines
92 KiB
Python
Executable File
2298 lines
92 KiB
Python
Executable File
from __future__ import absolute_import
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from __future__ import division
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# ** This is the file quisk_conf_defaults.py which contains defaults for Quisk. **
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#
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# Please do not change this configuration file quisk_conf_defaults.py.
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# Instead copy one of the other quisk_conf_*.py files to your own
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# configuration file and make changes there.
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#
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# For Linux, your standard configuration file name is .quisk_conf.py in your home directory.
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#
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# For Windows, your standard comfiguration file name is quisk_conf.py in your Documents folder.
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#
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# You can specify a different configuration file with the -c or --config command line argument.
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#
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# Check the config screen to make sure that the correct configuration file is in use.
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#
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#
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# PLEASE DO **NOT** COPY THIS FILE AND USE IT AS A START FOR YOUR CONFIGURATION FILE!
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# YOUR CONFIGURATION FILE SHOULD ONLY HAVE LINES THAT DIFFER FROM THIS FILE. QUISK
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# IMPORTS THIS FILE FIRST, AND THEN YOUR CONFIG FILE OVERWRITES A FEW ITEMS SUCH AS
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# SOUND CARD NAMES.
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#
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# Quisk imports quisk_conf_defaults.py to set its configuration.
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# If you have a configuration file, it then overwrites the defaults
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# with your parameters.
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#
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# Quisk uses a hardware file to control your transceiver and optionally other station hardware.
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# Your config file specifies the hardware file to use. Quisk comes with several hardware
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# files, and you can write your own hardware file in Python to do anything you want.
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#
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# Quisk has a custom decimation scheme for each sample rate. The allowable sample rates
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# are the four SDR-IQ rates plus 24, 48, 96, 192, 240, 384, 480, and 960 ksps. Other rates
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# can be added.
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import sys
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import wx
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# Import the default Hardware module. You can import a different module in
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# your configuration file.
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import quisk_hardware_model as quisk_hardware
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# Module for additional widgets (advanced usage). See n2adr/quisk_widgets.py for an example.
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# import n2adr.quisk_widgets as quisk_widgets
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quisk_widgets = None
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################ Receivers SoftRock USB, Devices controlled by USB that capture samples from a sound card, and (for Tx) play samples to a sound card
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## hardware_file_name Hardware file path, rfile
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# This is the file that contains the control logic for each radio.
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#hardware_file_name = 'softrock/hardware_usb.py'
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## widgets_file_name Widget file path, rfile
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# This optional file adds additional controls for the radio.
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#widgets_file_name = 'softrock/widgets_tx.py'
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use_sdriq = 0 # Get ADC samples from SDR-IQ is not used
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use_rx_udp = 0 # Get ADC samples from UDP is not used
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use_soapy = 0 # Get ADC samples from SoapySDR is not used
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sample_rate = 48000 # name_of_sound_capt hardware sample rate in Hertz
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if sys.platform == "win32":
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name_of_sound_capt = "Primary"
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name_of_sound_play = "Primary"
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elif sys.platform == "darwin":
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name_of_sound_capt = "pulse"
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name_of_sound_play = "pulse"
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else:
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name_of_sound_capt = "hw:0" # Name of soundcard capture hardware device.
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name_of_sound_play = "hw:0"
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channel_i = 0 # Soundcard index of in-phase channel: 0, 1, 2, ...
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channel_q = 1 # Soundcard index of quadrature channel: 0, 1, 2, ...
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## usb_vendor_id Vendor ID for USB control, integer
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# USB devices have a vendor ID and a product ID.
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usb_vendor_id = 0x16c0
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## usb_product_id Product ID for USB control, integer
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# USB devices have a vendor ID and a product ID.
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usb_product_id = 0x05dc
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# I2C-address of the Si570 in the softrock; Thanks to Joachim Schneider, DB6QS
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## si570_i2c_address I2C address, integer
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# I2C-address of the Si570 in the softrock.
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si570_i2c_address = 0x55
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#si570_i2c_address = 0x70
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# Thanks to Ethan Blanton, KB8OJH, for this patch for the Si570 (many SoftRock's):
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## si570_direct_control Use Si570 direct control, boolean
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# If you are using a DG8SAQ interface to set a Si570 clock directly, set
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# this to True. Complex controllers which have their own internal
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# crystal calibration do not require this.
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si570_direct_control = False
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#si570_direct_control = True
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## si570_xtal_freq Si570 crystal frequency, integer
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# This is the Si570 startup frequency in Hz. 114.285MHz is the typical
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# value from the data sheet; you can use 'usbsoftrock calibrate' to find
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# the value for your device.
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si570_xtal_freq = 114285000
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## key_poll_msec Key poll time msec, integer
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# Softrock hardware must be polled to get the key up/down state. This is the time between
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# polls in milliseconds. Use zero to turn off the poll if your SoftRock does not have a key
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# jack or USB key control.
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key_poll_msec = 0
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#key_poll_msec = 5
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## key_hang_time Key hang time secs, number
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# Softrock transmit hardware uses semi break-in for CW operation. This is the time in
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# seconds before changing back to receive.
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key_hang_time = 0.7
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## repeater_delay Repeater delay secs, number
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# The fixed delay for changing the repeater Rx/Tx frequency in seconds.
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repeater_delay = 0.25
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## rx_max_amplitude_correct Max ampl correct, number
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# If you get your I/Q samples from a sound card, you will need to correct the
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# amplitude and phase for inaccuracies in the analog hardware. The correction is
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# entered using the controls from the "Rx Phase" button on the config screen.
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# You must enter a positive number. This controls the range of the control.
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rx_max_amplitude_correct = 0.2
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## rx_max_phase_correct Max phase correct, number
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# If you get your I/Q samples from a sound card, you will need to correct the
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# amplitude and phase for inaccuracies in the analog hardware. The correction is
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# entered using the controls from the "Rx Phase" button on the config screen.
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# You must enter a positive number. This controls the range of the control in degrees.
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rx_max_phase_correct = 10.0
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## mic_out_volume Tx audio level, number
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# The level of the Tx audio sent to the sound card after all processing as a fraction 0.0 to 0.7.
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# The level is limited to 0.7 to allow headroom for amplitude and phase adjustments.
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mic_out_volume = 0.7
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# The bandAmplPhase dictionary gives the amplitude and phase corrections for
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# sound card data. The format is a dictionary with key "band", giving a dictionary
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# with key "rx" or "tx", giving a list of tuples (VFO, tune, amplitude, phase).
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#
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# If you use Quisk as a panadapter, the corrections will not depend on the band.
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# In that case create a band "panadapter" in your config file, and all corrections
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# will be read/written to that band.
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bandAmplPhase = {} # Empty dictionary to start
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#bandAmplPhase = {'panadapter':{}} # Create "panadapter" band for all corrections
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################ Receivers SoftRock Fixed, Fixed frequency devices that capture samples from a sound card, and (for Tx) play samples to a sound card
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## hardware_file_name Hardware file path, rfile
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# This is the file that contains the control logic for each radio.
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#hardware_file_name = 'quisk_hardware_fixed.py'
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## widgets_file_name Widget file path, rfile
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# This optional file adds additional controls for the radio.
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#widgets_file_name = ''
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## fixed_vfo_freq Fixed VFO frequency, integer
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# The fixed VFO frequency. That is, the frequency in the center of the screen.
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fixed_vfo_freq = 7056000
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## rx_max_amplitude_correct Max ampl correct, number
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# If you get your I/Q samples from a sound card, you will need to correct the
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# amplitude and phase for inaccuracies in the analog hardware. The correction is
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# entered using the controls from the "Rx Phase" button on the config screen.
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# No correction is 1.00. This controls the range of the control.
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rx_max_amplitude_correct = 0.2
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## rx_max_phase_correct Max phase correct, number
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# If you get your I/Q samples from a sound card, you will need to correct the
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# amplitude and phase for inaccuracies in the analog hardware. The correction is
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# entered using the controls from the "Rx Phase" button on the config screen.
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# No correction is 0.00. This controls the range of the control in degrees.
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rx_max_phase_correct = 10.0
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## mic_out_volume Tx audio level, number
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# The level of the Tx audio sent to the sound card after all processing as a fraction 0.0 to 0.7.
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# The level is limited to 0.7 to allow headroom for amplitude and phase adjustments.
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mic_out_volume = 0.7
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# The bandAmplPhase dictionary gives the amplitude and phase corrections for
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# sound card data. The format is a dictionary with key "band", giving a dictionary
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# with key "rx" or "tx", giving a list of tuples (VFO, tune, amplitude, phase).
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#
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# If you use Quisk as a panadapter, the corrections will not depend on the band.
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# In that case create a band "panadapter" in your config file, and all corrections
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# will be read/written to that band.
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bandAmplPhase = {} # Empty dictionary to start
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#bandAmplPhase = {'panadapter':{}} # Create "panadapter" band for all corrections
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################ Receivers HiQSDR, The original N2ADR hardware and the improved HiQSDR using UDP
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## hardware_file_name Hardware file path, rfile
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# This is the file that contains the control logic for each radio.
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#hardware_file_name = 'hiqsdr/quisk_hardware.py'
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## widgets_file_name Widget file path, rfile
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# This optional file adds additional controls for the radio.
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#widgets_file_name = ''
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# For the N2ADR 2010 transceiver described in QEX, and for the improved version HiQSDR,
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# see the sample config file in the hiqsdr package directory, and set these:
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## use_rx_udp Hardware type, integer choice
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# This is the type of UDP hardware. Use 1 for the original hardware by N2ADR.
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# Use 2 for the HiQSDR.
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#use_rx_udp = 2
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#use_rx_udp = 1
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#use_rx_udp = 17
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## tx_level Tx Level, dict
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# tx_level sets the transmit level 0 to 255 for each band. The None band is the default.
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# The config screen has a slider 0 to 100% so you can reduce the transmit power. The sliders
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# only appear if your hardware defines the method SetTxLevel(). The hardware only supports a
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# power adjustment range of 20 dB, so zero is still a small amount of power.
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tx_level = {
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None:120, '60':110}
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## digital_tx_level Digital Tx power %, integer
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# Digital modes reduce power by the percentage on the config screen.
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# This is the maximum value of the slider.
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digital_tx_level = 20
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## HiQSDR_BandDict IO Bus, dict
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# If you use the HiQSDR hardware, set these:
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# The HiQSDR_BandDict sets the preselect (4 bits) on the X1 connector.
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HiQSDR_BandDict = {
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'160':1, '80':2, '40':3, '30':4, '20':5, '15':6, '17':7,
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'12':8, '10':9, '6':10, '500k':11, '137k':12 }
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## cw_delay CW Delay, integer
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# This is the delay for CW from 0 to 255.
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cw_delay = 0
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## rx_udp_ip IP address, text
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# This is the IP address of your hardware.
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# For FPGA firmware version 1.4 and newer, and if enabled, the hardware is set to the IP address you enter here.
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# For older firmware, the IP address is programmed into the FPGA, and you must enter that address.
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rx_udp_ip = "192.168.2.196"
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#rx_udp_ip = "192.168.1.196"
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## rx_udp_port Hardware UDP port, integer
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# This is the base UDP port number of your hardware.
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rx_udp_port = 0xBC77
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## rx_udp_ip_netmask Network netmask, text
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# This is the netmask for the network.
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rx_udp_ip_netmask = '255.255.255.0'
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## tx_ip Transmit IP, text
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# Leave this blank to use the same IP address as the receive hardware. Otherwise, enter "disable"
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# to disable sending transmit I/Q samples, or enter the actual IP address. You must enter "disable"
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# if you have multiple hardwares on the network, and only one should transmit.
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tx_ip = ""
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#tx_ip = "disable"
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#tx_ip = "192.168.1.201"
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## tx_audio_port Tx audio UDP port, integer
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# This is the UDP port for transmit audio I/Q samples. Enter zero to calculate this from the
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# base hardware port. Otherwise enter the special custom port.
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tx_audio_port = 0
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## rx_udp_clock Clock frequency Hertz, integer
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# This is the clock frequency of the hardware in Hertz.
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rx_udp_clock = 122880000
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## sndp_active Enable setting IP, boolean
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# If possible, set the IP address to the address entered.
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# For FPGA firmware version 1.4 and newer, the hardware is set to the IP address you enter here.
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# For older firmware, the IP address is programmed into the FPGA, and you must enter that address.
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sndp_active = True
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#sndp_active = False
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################ Receivers Hermes, The Hermes-Lite Project and possibly other hardware with the Hermes FPGA code.
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## hardware_file_name Hardware file path, rfile
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# This is the file that contains the control logic for each radio.
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#hardware_file_name = 'hermes/quisk_hardware.py'
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## widgets_file_name Widget file path, rfile
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# This optional file adds additional controls for the radio.
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#widgets_file_name = 'hermes/quisk_widgets.py'
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# Quisk has support for the Hermes-Lite project. This support will be extended to the original Hermes.
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# Use the file hermes/quisk_conf.py as a model config file. The Hermes can obtain its IP address from
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# DHCP. Set rx_udp_ip to the null string in this case. Or use rx_udp_ip to specify an IP address, but
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# be sure it is unique and not in use by a DHCP server. The tx_ip and tx_audio_port are not used.
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# Note: Setting the IP fails for the Hermes-Lite.
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# You can set these options:
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## use_rx_udp Hardware type, integer choice
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# This is the type of UDP hardware. Use 10 for the Hermes protocol.
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#use_rx_udp = 10
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## udp_rx_ip Hermes known IP, text
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# Leave this blank to find the Hermes hardware with the usual UDP broadcast method.
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# But this will not work on a VPN or when broadcasts are not routed
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# to remote networks. In that case, enter the known IP address of the Hermes hardware.
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udp_rx_ip = ''
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#udp_rx_ip = '192.168.1.86'
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## rx_udp_port Hardware UDP port, integer
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# This is the UDP port number of your hardware.
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#rx_udp_port = 1024
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## rx_udp_ip IP change, text
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# This item should be left blank. It is used to change the IP address of the hardware to a different
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# IP once the hardware is found by the broadcast method. Not all Hermes firmware supports changing the IP address.
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#rx_udp_ip = ""
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## tx_ip Transmit IP, text
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# Leave this blank to use the same IP address as the receive hardware. Otherwise, enter "disable"
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# to disable sending transmit I/Q samples, or enter the actual IP address. You must enter "disable"
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# if you have multiple hardwares on the network, and only one should transmit. This item is normally blank.
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tx_ip = ""
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#tx_ip = "disable"
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## tx_audio_port Tx audio UDP port, integer
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# This is the UDP port for transmit audio I/Q samples. Enter zero to calculate this from the
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# base hardware port. Otherwise enter the special custom port.
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tx_audio_port = 0
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## rx_udp_clock Clock frequency Hertz, integer
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# This is the clock frequency of the hardware in Hertz. For HermesLite ver2 use 76800000.
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#rx_udp_clock = 73728000
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#rx_udp_clock = 61440000
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#rx_udp_clock = 76800000
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## tx_level Tx Level, dict
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# tx_level sets the transmit level 0 to 255 for each band. The None band is the default.
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# The config screen has a slider 0 to 100% so you can reduce the transmit power. The sliders
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# only appear if your hardware defines the method SetTxLevel(). The hardware only supports a
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# limited adjustment range, so zero is still a small amount of power.
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tx_level = {
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None:120, '60':110}
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## digital_tx_level Digital Tx power %, integer
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# Digital modes reduce power by the percentage on the config screen.
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# This is the maximum value of the slider.
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#digital_tx_level = 20
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## hermes_code_version Hermes code version, integer
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# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
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# hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
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hermes_code_version = -1
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## hermes_board_id Hermes board ID, integer
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# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
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# hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
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hermes_board_id = -1
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## hermes_LNA_dB Initial LNA dB, integer
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# The initial value for the low noise Rx amplifier gain in dB.
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hermes_LNA_dB = 20
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## hermes_lowpwr_tr_enable Disable T/R in low power, boolean
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# This option only applies to the Hermes Lite 2.
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# Normally, the T/R relay and external PTT output switch on and off when keying the transmitter.
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# But if you set this option, and if you are in low power mode (final amp off) then the T/R relay
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# remains in receive mode. This is useful for VNA operation as you can use the low power Tx output
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# as the generator and the normal connector as the detector.
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# Changes are immediate (no need to restart).
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hermes_lowpwr_tr_enable = False
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#hermes_lowpwr_tr_enable = True
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## hermes_bias_adjust Enable bias adjust, boolean
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# This option only applies to the Hermes Lite 2.
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# Below are controls that adjust the bias on the power output transistors. Before you enable adjustment,
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# make sure you know the correct drain current and how to monitor the current.
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# Then set this to True. When you are finished, set it back to False. The bias adjustment
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# is stored in the hardware only when the "Write" button is pressed.
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# Changes are immediate (no need to restart).
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hermes_bias_adjust = False
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#hermes_bias_adjust = True
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## hermes_power_amp Enable power amp, boolean
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# This option only applies to the Hermes Lite 2.
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# When True, the power amp is turned on. Otherwise, the low power output is used.
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# Changes are immediate (no need to restart).
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hermes_power_amp = False
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#hermes_power_amp = True
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## power_meter_calib_name Power meter calibration, text choice
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# This is the calibration table used to convert the power sensor voltage measured by the ADC to the transmit power display.
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# It is a table of ADC codes and the corresponding measured power level. If you have a power meter, you can create your own
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# table by selecting "New". Then enter ten or more power measurements from low to full power.
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# For the Hermes-Lite version E3 filter board, use the built-in table "HL2FilterE3".
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# Changes are immediate (no need to restart).
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power_meter_calib_name = 'HL2FilterE3'
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## hermes_disable_sync Disable Power Supply Sync, boolean
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# This option only applies to the Hermes Lite 2.
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# When True, the FPGA will not generate a switching frequency for the power supply to
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# move the harmonics out of amateur bands.
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# Changes are immediate (no need to restart).
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hermes_disable_sync = False
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#hermes_disable_sync = True
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## Hware_Hl2_EepromIP Eeprom IP Address, text
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# This is the IP address stored in the Hermes Lite EEPROM. It is only used at power on. If you set an address here
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# be sure to write it down. And you may want to set "Hermes known IP" too. Make sure the address does not conflict
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# with your DHCP server.
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Hware_Hl2_EepromIP = '192.168.1.6'
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#Hware_Hl2_EepromIP = '192.168.1.241'
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## Hware_Hl2_EepromIPUse Eeprom IP Usage, text choice
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# This is the way the EEPROM IP address is used at power on.
|
|
# "Ignore" means it is not used at all. "Set address" means DHCP is not used and the EEPROM IP address is used.
|
|
# "Use DHCP first" means the EEPROM IP address is only used if DHCP fails.
|
|
Hware_Hl2_EepromIPUse = 'Ignore'
|
|
#Hware_Hl2_EepromIPUse = 'Use DHCP first'
|
|
#Hware_Hl2_EepromIPUse = 'Set address'
|
|
|
|
## Hware_Hl2_EepromMAC Eeprom MAC Address, text
|
|
# This is two numbers to be used as the last two bytes of the MAC address. It is only used at power on.
|
|
# If you have multiple Hermes Lites, each one must have a different MAC address.
|
|
Hware_Hl2_EepromMAC = '0xA1 0x6B'
|
|
#Hware_Hl2_EepromMAC = '0x4C 0x33'
|
|
|
|
## Hware_Hl2_EepromMACUse Eeprom MAC Usage, text choice
|
|
# This is the way the EEPROM MAC address is used at power on.
|
|
# "Ignore" means it is not used at all. "Set address" means the address is used.
|
|
Hware_Hl2_EepromMACUse = 'Ignore'
|
|
#Hware_Hl2_EepromMACUse = 'Set address'
|
|
|
|
## hermes_TxLNA_dB LNA during Tx dB, integer
|
|
# During transmit the low noise Rx amplifier gain changes to this value (in dB) if the hardware supports it.
|
|
# Changes are immediate (no need to restart).
|
|
hermes_TxLNA_dB = 21
|
|
|
|
# These are known power meter calibration tables. This table is not present in the JSON settings file.
|
|
power_meter_std_calibrations = {}
|
|
power_meter_std_calibrations['HL2FilterE3'] = [[ 0, 0.0 ], [ 25.865384615384617, 0.0025502539351328003 ], [ 101.02453987730061, 0.012752044999999998 ],
|
|
[ 265.2901234567901, 0.050600930690879994 ], [ 647.9155844155844, 0.21645831264800003 ], [ 1196.5935483870967, 0.66548046472992 ],
|
|
[ 1603.7032258064517, 1.1557229391679997 ], [ 2012.3271604938273, 1.811892166688 ], [ 2616.7727272727275, 3.0085848760319993 ],
|
|
[ 3173.818181818182, 4.3927428485119995 ], [ 3382.7922077922076, 4.9791328857920005 ], [ 3721.0714285714284, 6.024750791808321 ],
|
|
[ 4093.1785714285716, 7.28994845808807 ], [ 4502.496428571429, 8.820837634286566 ], [ 4952.746071428572, 10.673213537486745 ] ]
|
|
#power_meter_std_calibrations['HL2FilterE1'] = [[0, 0.0], [9.07, 0.002], [54.98, 0.014], [148.6, 0.057],
|
|
# [328.0, 0.208], [611.1, 0.646], [807.0, 1.098], [982.1, 1.6], [1223.3, 2.471], [1517.7, 3.738], [1758.7, 5.02]]
|
|
|
|
## Hermes_BandDict Rx IO Bus, dict
|
|
# The Hermes_BandDict sets the 7 bits on the J16 connector for Rx.
|
|
Hermes_BandDict = {
|
|
'160':0b0000001, '80':0b1000010, '60':0b1000100, '40':0b1000100, '30':0b1001000, '20':0b1001000, '17':0b1010000,
|
|
'15':0b1010000, '12':0b1100000, '10':0b1100000}
|
|
|
|
## Hermes_BandDictTx Tx IO Bus, dict
|
|
# The Hermes_BandDictTx sets the 7 bits on the J16 connector for Tx if enabled.
|
|
Hermes_BandDictTx = {'160':0, '80':0, '60':0, '40':0, '30':0, '20':0, '17':0, '15':0, '12':0, '10':0}
|
|
|
|
## Hermes_BandDictEnTx Enable Tx Filt, boolean
|
|
# Enable the separate Rx and Tx settings for the J16 connector.
|
|
Hermes_BandDictEnTx = False
|
|
#Hermes_BandDictEnTx = True
|
|
|
|
## AlexHPF Alex High Pass Filters, list
|
|
# This is a list of frequencies and high pass filter settings.
|
|
AlexHPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
## AlexLPF Alex Low Pass Filters, list
|
|
# This is a list of frequencies and low pass filter settings.
|
|
AlexLPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
|
|
## AlexHPF_TxEn Alex HPF Tx Enable, boolean
|
|
AlexHPF_TxEn = False
|
|
#AlexHPF_TxEn = True
|
|
|
|
## AlexLPF_TxEn Alex LPF Tx Enable, boolean
|
|
AlexLPF_TxEn = False
|
|
#AlexLPF_TxEn = True
|
|
|
|
|
|
################ Receivers Red Pitaya, The Red Pitaya Project by Pavel Demin. This uses the Hermes FPGA code.
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
#hardware_file_name = 'hermes/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = ''
|
|
|
|
## use_rx_udp Hardware type, integer choice
|
|
# This is the type of UDP hardware. Use 10 for the Hermes protocol.
|
|
#use_rx_udp = 10
|
|
|
|
## rx_udp_ip IP change, text
|
|
# This item should be left blank. It is used to change the IP address of the hardware to a different
|
|
# IP once the hardware is found. Not all Hermes firmware supports changing the IP address.
|
|
#rx_udp_ip = ""
|
|
|
|
## rx_udp_port Hardware UDP port, integer
|
|
# This is the UDP port number of your hardware.
|
|
#rx_udp_port = 1024
|
|
|
|
## rx_udp_ip_netmask Network netmask, text
|
|
# This is the netmask for the network.
|
|
#rx_udp_ip_netmask = '255.255.255.0'
|
|
|
|
## tx_ip Transmit IP, text
|
|
# Leave this blank to use the same IP address as the receive hardware. Otherwise, enter "disable"
|
|
# to disable sending transmit I/Q samples, or enter the actual IP address. You must enter "disable"
|
|
# if you have multiple hardwares on the network, and only one should transmit. This item is normally blank.
|
|
tx_ip = ""
|
|
#tx_ip = "disable"
|
|
|
|
## tx_audio_port Tx audio UDP port, integer
|
|
# This is the UDP port for transmit audio I/Q samples. Enter zero to calculate this from the
|
|
# base hardware port. Otherwise enter the special custom port.
|
|
tx_audio_port = 0
|
|
|
|
## rx_udp_clock Clock frequency Hertz, integer
|
|
# This is the clock frequency of the hardware in Hertz.
|
|
#rx_udp_clock = 125000000
|
|
|
|
## tx_level Tx Level, dict
|
|
# tx_level sets the transmit level 0 to 255 for each band. The None band is the default.
|
|
# The config screen has a slider 0 to 100% so you can reduce the transmit power. The sliders
|
|
# only appear if your hardware defines the method SetTxLevel(). The hardware only supports a
|
|
# limited adjustment range, so zero is still a small amount of power.
|
|
tx_level = {
|
|
None:120, '60':110}
|
|
|
|
## digital_tx_level Digital Tx power %, integer
|
|
# Digital modes reduce power by the percentage on the config screen.
|
|
# This is the maximum value of the slider.
|
|
#digital_tx_level = 20
|
|
|
|
## hermes_code_version Hermes code version, integer
|
|
# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
|
|
# hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
|
|
hermes_code_version = -1
|
|
|
|
## hermes_board_id Hermes board ID, integer
|
|
# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
|
|
# hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
|
|
hermes_board_id = -1
|
|
|
|
## hermes_LNA_dB Initial LNA dB, integer
|
|
# The initial value for the low noise Rx amplifier gain in dB.
|
|
hermes_LNA_dB = 20
|
|
|
|
## Hermes_BandDict Hermes Bus, dict
|
|
# The Hermes_BandDict sets the 7 bits on the J16 connector.
|
|
Hermes_BandDict = {
|
|
'160':0b0000001, '80':0b0000010, '60':0b0000100, '40':0b0001000, '30':0b0010000, '20':0b0100000, '15':0b1000000}
|
|
|
|
## Hermes_BandDictTx Tx IO Bus, dict
|
|
# The Hermes_BandDictTx sets the 7 bits on the J16 connector for Tx if enabled.
|
|
Hermes_BandDictTx = {'160':0, '80':0, '60':0, '40':0, '30':0, '20':0, '17':0, '15':0, '12':0, '10':0}
|
|
|
|
## Hermes_BandDictEnTx Enable Tx Filt, boolean
|
|
# Enable the separate Rx and Tx settings for the J16 connector.
|
|
Hermes_BandDictEnTx = False
|
|
#Hermes_BandDictEnTx = True
|
|
|
|
## AlexHPF Alex High Pass Filters, list
|
|
# This is a list of frequencies and high pass filter settings.
|
|
AlexHPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
|
|
## AlexLPF Alex Low Pass Filters, list
|
|
# This is a list of frequencies and low pass filter settings.
|
|
AlexLPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
|
|
## AlexHPF_TxEn Alex HPF Tx Enable, boolean
|
|
AlexHPF_TxEn = False
|
|
#AlexHPF_TxEn = True
|
|
|
|
## AlexLPF_TxEn Alex LPF Tx Enable, boolean
|
|
AlexLPF_TxEn = False
|
|
#AlexLPF_TxEn = True
|
|
|
|
|
|
################ Receivers SoapySDR, The SoapySDR interface to multiple hardware SDRs.
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
#hardware_file_name = 'soapypkg/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = ''
|
|
|
|
## use_soapy Use SoapySDR, integer
|
|
# Enter 1 to turn on SoapySDR.
|
|
#use_soapy = 1
|
|
|
|
# Further items are present in the radio dictionary with names soapy_*
|
|
|
|
|
|
################ Receivers SdrIQ, The SDR-IQ receiver by RfSpace
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
hardware_file_name = 'quisk_hardware_sdriq.py'
|
|
#hardware_file_name = 'sdriqpkg/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = ''
|
|
|
|
#
|
|
# For the SDR-IQ the soundcard is not used for capture.
|
|
|
|
sdriq_decimation = 1250
|
|
|
|
## use_sdriq Hardware by RF-Space, integer choice
|
|
# This is the type of hardware. For the SdrIQ, use_sdriq is 1.
|
|
#use_sdriq = 1
|
|
|
|
## sdriq_name Serial port, text
|
|
# The name of the SDR-IQ serial port to open.
|
|
#sdriq_name = "/dev/ttyUSB0"
|
|
#sdriq_name = "COM6"
|
|
#sdriq_name = "/dev/ft2450"
|
|
|
|
## sdriq_clock Clock frequency Hertz, number
|
|
# This is the clock frequency of the hardware in Hertz.
|
|
#sdriq_clock = 66666667.0
|
|
|
|
|
|
|
|
################ Receivers Odyssey, The Odyssey project using a UDP protocol similar to the HiQSDR
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
#hardware_file_name = 'hiqsdr/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = ''
|
|
|
|
## use_rx_udp Hardware type, integer choice
|
|
# This is the type of UDP hardware. The Odyssey uses type 2.
|
|
#use_rx_udp = 2
|
|
|
|
## tx_level Tx Level, dict
|
|
# tx_level sets the transmit level 0 to 255 for each band. The None band is the default.
|
|
# The config screen has a slider 0 to 100% so you can reduce the transmit power. The sliders
|
|
# only appear if your hardware defines the method SetTxLevel(). The hardware only supports a
|
|
# power adjustment range of 20 dB, so zero is still a small amount of power.
|
|
tx_level = {
|
|
None:120, '60':110}
|
|
|
|
## digital_tx_level Digital Tx power %, integer
|
|
# Digital modes reduce power by the percentage on the config screen.
|
|
# This is the maximum value of the slider.
|
|
digital_tx_level = 20
|
|
|
|
## HiQSDR_BandDict IO Bus, dict
|
|
# This sets the preselect (4 bits) on the X1 connector.
|
|
HiQSDR_BandDict = {
|
|
'160':1, '80':2, '40':3, '30':4, '20':5, '15':6, '17':7,
|
|
'12':8, '10':9, '6':10, '500k':11, '137k':12 }
|
|
|
|
## cw_delay CW Delay, integer
|
|
# This is the delay for CW from 0 to 255.
|
|
cw_delay = 0
|
|
|
|
## rx_udp_ip IP address, text
|
|
# This is the IP address of your hardware.
|
|
# For FPGA firmware version 1.4 and newer, and if enabled, the hardware is set to the IP address you enter here.
|
|
# For older firmware, the IP address is programmed into the FPGA, and you must enter that address.
|
|
rx_udp_ip = "192.168.2.160"
|
|
#rx_udp_ip = "192.168.1.196"
|
|
|
|
## rx_udp_port Hardware UDP port, integer
|
|
# This is the UDP port number of your hardware.
|
|
rx_udp_port = 48247
|
|
|
|
## rx_udp_ip_netmask Network netmask, text
|
|
# This is the netmask for the network.
|
|
rx_udp_ip_netmask = '255.255.255.0'
|
|
|
|
## tx_ip Transmit IP, text
|
|
# Leave this blank to use the same IP address as the receive hardware. Otherwise, enter "disable"
|
|
# to disable sending transmit I/Q samples, or enter the actual IP address. You must enter "disable"
|
|
# if you have multiple hardwares on the network, and only one should transmit.
|
|
tx_ip = ""
|
|
#tx_ip = "disable"
|
|
#tx_ip = "192.168.1.201"
|
|
|
|
## tx_audio_port Tx audio UDP port, integer
|
|
# This is the UDP port for transmit audio I/Q samples. Enter zero to calculate this from the
|
|
# base hardware port. Otherwise enter the special custom port.
|
|
tx_audio_port = 0
|
|
|
|
## rx_udp_clock Clock frequency Hertz, integer
|
|
# This is the clock frequency of the hardware in Hertz.
|
|
rx_udp_clock = 122880000
|
|
|
|
## sndp_active Enable setting IP, boolean
|
|
# If possible, set the IP address to the address entered.
|
|
# For FPGA firmware version 1.4 and newer, the hardware is set to the IP address you enter here.
|
|
# For older firmware, the IP address is programmed into the FPGA, and you must enter that address.
|
|
sndp_active = True
|
|
#sndp_active = False
|
|
|
|
## radio_sound_ip IP sound play, text
|
|
# This option sends radio playback sound to a UDP device. Some SDR hardware devices have an
|
|
# audio codec that can play radio sound with less latency than a soundcard. The sample rate
|
|
# is the same as the soundcard sample rate, but probably you will want 48000 sps. The UDP
|
|
# data consists of two bytes of zero, followed by the specified number of samples. Each
|
|
# sample consists of two bytes (a short) of I data and two bytes of Q data in little-endian order.
|
|
# For radio_sound_nsamples = 360, the total number of UDP data bytes is 1442.
|
|
#radio_sound_ip = "192.168.2.160"
|
|
|
|
## radio_sound_port UDP port play, integer
|
|
# The UDP port of the radio sound play device.
|
|
#radio_sound_port = 48250
|
|
|
|
## radio_sound_nsamples Num play samples, integer
|
|
# The number of play samples per UDP block.
|
|
#radio_sound_nsamples = 360
|
|
|
|
## radio_sound_mic_ip IP microphone, text
|
|
# This option receives microphone samples from a UDP device. The UDP
|
|
# data consists of two bytes of zero, followed by the specified number of samples. Each
|
|
# sample consists of two bytes (a short) of monophonic microphone data in little-endian order.
|
|
# For radio_sound_mic_nsamples = 720, the total number of UDP data bytes is 1442.
|
|
#radio_sound_mic_ip = "192.168.2.160"
|
|
|
|
## radio_sound_mic_port UDP port mic, integer
|
|
# The UDP port of the microphone device.
|
|
#radio_sound_mic_port = 48251
|
|
|
|
## radio_sound_mic_nsamples Num mic samples, integer
|
|
# The number of mic samples per UDP block.
|
|
#radio_sound_mic_nsamples = 720
|
|
|
|
## radio_sound_mic_boost Mic boost, boolean
|
|
# Use False for no microphone boost, or True for +20 dB boost.
|
|
#radio_sound_mic_boost = False
|
|
#radio_sound_mic_boost = True
|
|
|
|
|
|
################ Receivers Odyssey2, The Odyssey-2 project using the HPSDR Hermes protocol
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
#hardware_file_name = 'hermes/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = 'hermes/quisk_widgets.py'
|
|
|
|
# Use the file hermes/quisk_conf.py as a model config file. The Hermes can obtain its IP address from
|
|
# DHCP. Set rx_udp_ip to the null string in this case. Or use rx_udp_ip to specify an IP address, but
|
|
# be sure it is unique and not in use by a DHCP server.
|
|
# You can set these options:
|
|
|
|
## use_rx_udp Hardware type, integer choice
|
|
# This is the type of UDP hardware. Use 10 for the Hermes protocol.
|
|
#use_rx_udp = 10
|
|
|
|
## rx_udp_ip IP change, text
|
|
# This item should be left blank. It is used to change the IP address of the hardware to a different
|
|
# IP once the hardware is found. Not all Hermes firmware supports changing the IP address.
|
|
#rx_udp_ip = ""
|
|
|
|
## rx_udp_port Hardware UDP port, integer
|
|
# This is the UDP port number of your hardware.
|
|
#rx_udp_port = 1024
|
|
|
|
## rx_udp_ip_netmask Network netmask, text
|
|
# This is the netmask for the network.
|
|
#rx_udp_ip_netmask = '255.255.255.0'
|
|
|
|
## tx_ip Transmit IP, text
|
|
# Leave this blank to use the same IP address as the receive hardware. Otherwise, enter "disable"
|
|
# to disable sending transmit I/Q samples, or enter the actual IP address. You must enter "disable"
|
|
# if you have multiple hardwares on the network, and only one should transmit. This item is normally blank.
|
|
tx_ip = ""
|
|
#tx_ip = "disable"
|
|
|
|
## tx_audio_port Tx audio UDP port, integer
|
|
# This is the UDP port for transmit audio I/Q samples. Enter zero to calculate this from the
|
|
# base hardware port. Otherwise enter the special custom port.
|
|
tx_audio_port = 0
|
|
|
|
## rx_udp_clock Clock frequency Hertz, integer
|
|
# This is the clock frequency of the hardware in Hertz. For Odyssey use 122880000.
|
|
#rx_udp_clock = 122880000
|
|
|
|
## tx_level Tx Level, dict
|
|
# tx_level sets the transmit level 0 to 255 for each band. The None band is the default.
|
|
# The config screen has a slider 0 to 100% so you can reduce the transmit power. The sliders
|
|
# only appear if your hardware defines the method SetTxLevel(). The hardware only supports a
|
|
# limited adjustment range, so zero is still a small amount of power.
|
|
tx_level = {
|
|
None:120, '60':110}
|
|
|
|
## digital_tx_level Digital Tx power %, integer
|
|
# Digital modes reduce power by the percentage on the config screen.
|
|
# This is the maximum value of the slider.
|
|
#digital_tx_level = 20
|
|
|
|
|
|
## hermes_code_version Hermes code version, integer
|
|
# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
|
|
# Hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
|
|
hermes_code_version = -1
|
|
|
|
## hermes_board_id Hermes board ID, integer
|
|
# There can be multiple Hermes devices on a network, but Quisk can only use one of these. If you have multiple
|
|
# Hermes devices, you can use this to specify a unique device. Or use -1 to accept any board.
|
|
hermes_board_id = -1
|
|
|
|
## hermes_LNA_dB Initial LNA dB, integer
|
|
# The initial value for the low noise Rx amplifier gain in dB.
|
|
hermes_LNA_dB = 20
|
|
|
|
## Hermes_BandDict Hermes Bus, dict
|
|
# The Hermes_BandDict sets the 7 bits on the J16 connector.
|
|
Hermes_BandDict = {
|
|
'160':0b0000001, '80':0b0000010, '60':0b0000100, '40':0b0001000, '30':0b0010000, '20':0b0100000, '15':0b1000000}
|
|
|
|
## Hermes_BandDictTx Tx IO Bus, dict
|
|
# The Hermes_BandDictTx sets the 7 bits on the J16 connector for Tx if enabled.
|
|
Hermes_BandDictTx = {'160':0, '80':0, '60':0, '40':0, '30':0, '20':0, '17':0, '15':0, '12':0, '10':0}
|
|
|
|
## Hermes_BandDictEnTx Enable Tx Filt, boolean
|
|
# Enable the separate Rx and Tx settings for the J16 connector.
|
|
Hermes_BandDictEnTx = False
|
|
#Hermes_BandDictEnTx = True
|
|
|
|
## AlexHPF Alex High Pass Filters, list
|
|
# This is a list of frequencies and high pass filter settings.
|
|
AlexHPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
|
|
## AlexLPF Alex Low Pass Filters, list
|
|
# This is a list of frequencies and low pass filter settings.
|
|
AlexLPF = [
|
|
['3.0', '4.5', 0, 0], ['6.5', '8.5', 0, 0]] + [['', '', 0, 0]] * 6
|
|
|
|
## AlexHPF_TxEn Alex HPF Tx Enable, boolean
|
|
AlexHPF_TxEn = False
|
|
#AlexHPF_TxEn = True
|
|
|
|
## AlexLPF_TxEn Alex LPF Tx Enable, boolean
|
|
AlexLPF_TxEn = False
|
|
#AlexLPF_TxEn = True
|
|
|
|
|
|
################ Receivers Afedri, The Afedri SDR receiver with the Ethernet interface.
|
|
## hardware_file_name Hardware file path, rfile
|
|
# This is the file that contains the control logic for each radio.
|
|
#hardware_file_name = 'afedrinet/quisk_hardware.py'
|
|
|
|
## widgets_file_name Widget file path, rfile
|
|
# This optional file adds additional controls for the radio.
|
|
#widgets_file_name = ''
|
|
|
|
## rx_udp_ip IP address, text
|
|
# This is the IP address of your hardware. Enter 0.0.0.0 to search for the address.
|
|
#rx_udp_ip = "0.0.0.0"
|
|
#rx_udp_ip = "192.168.0.200"
|
|
#rx_udp_ip = "192.168.1.196"
|
|
|
|
## rx_udp_port Hardware UDP port, integer
|
|
# This is the base UDP port number of your hardware.
|
|
#rx_udp_port = 50000
|
|
|
|
## rx_udp_ip_netmask Network netmask, text
|
|
# This is the netmask for the network.
|
|
#rx_udp_ip_netmask = '255.255.255.0'
|
|
|
|
## rx_udp_clock Clock frequency Hertz, integer
|
|
# This is the clock frequency of the hardware in Hertz.
|
|
#rx_udp_clock = 80000000
|
|
|
|
## default_rf_gain Default RF gain, integer
|
|
# This is the RF gain when starting.
|
|
#default_rf_gain = 11
|
|
|
|
|
|
################ Sound Devices. Quisk recognizes eight sound capture and playback devices.
|
|
# Playback devices:
|
|
# name_of_sound_play Play radio sound on speakers or headphones
|
|
# playback_rate The sample rate, normally 48000, 96000 or 192000
|
|
# name_of_mic_play For sound card modes (like SoftRock), play I/Q transmit audio
|
|
# mic_playback_rate The sample rate
|
|
# mic_play_chan_I Channel number 0, 1, ... for I samples
|
|
# mic_play_chan_Q Channel number 0, 1, ... for Q samples
|
|
# tx_channel_delay Channel number for delay, or -1
|
|
# digital_output_name Output monophonic digital samples to another program
|
|
# sample_playback_name Output digital I/Q samples to another program
|
|
# digital_rx1_name Output monophonic digital samples from Rx1 to another program
|
|
# Capture devices:
|
|
# microphone_name The monophonic microphone source
|
|
# mic_sample_rate The sample rate; must be 48000
|
|
# mic_channel_I The channel number for samples
|
|
# mic_channel_Q Not used.
|
|
# name_of_sound_capt For sound card modes (like SoftRock), capture I/Q samples
|
|
# sample_rate The sample rate
|
|
# channel_i Channel number 0, 1, ... for I samples
|
|
# channel_q Channel number 0, 1, ... for Q samples
|
|
# channel_delay Channel number for delay, or -1
|
|
# digital_input_name Receive monophonic digital samples from another program
|
|
#
|
|
# Unused devices have the null string "" as the name. For example, name_of_sound_play="" for a panadapter.
|
|
#
|
|
# On Linux, Quisk can access your sound card through ALSA, PortAudio or PulseAudio.
|
|
# On Windows, Quisk uses DirectX for sound card access.
|
|
|
|
## channel_i Sample channel I, integer
|
|
# Soundcard index of in-phase channel: 0, 1, 2, ...
|
|
channel_i = 0
|
|
#channel_i = 1
|
|
|
|
## channel_q Sample channel Q, integer
|
|
# Soundcard index of quadrature channel: 0, 1, 2, ...
|
|
channel_q = 1
|
|
#channel_q = 0
|
|
|
|
# Thanks to Franco Spinelli for this fix:
|
|
## channel_delay Rx channel delay, integer
|
|
# The H101 hardware using the PCM2904 chip has a one-sample delay between
|
|
# channels, which must be fixed in software. If you have this problem,
|
|
# change channel_delay to either channel_i or channel_q. Use -1 for no delay.
|
|
channel_delay = -1
|
|
#channel_delay = 0
|
|
#channel_delay = 1
|
|
|
|
## tx_channel_delay Tx channel delay, integer
|
|
# This is for mic playback (SoftRock transmit)
|
|
tx_channel_delay = -1
|
|
#tx_channel_delay = 0
|
|
#tx_channel_delay = 1
|
|
|
|
## playback_rate Playback rate, integer choice
|
|
# This is the received radio sound playback rate. The default will
|
|
# be 48 kHz for the SDR-IQ and UDP port samples, and sample_rate for sound
|
|
# card capture. Set it yourself for other rates or hardware.
|
|
# The playback_rate must be 24000, 48000, 96000 or 192000.
|
|
# The preferred rate is 48000 for use with digital modes and transmit of recorded audio.
|
|
#playback_rate = 48000
|
|
#playback_rate = 24000
|
|
#playback_rate = 96000
|
|
#playback_rate = 192000
|
|
|
|
## lin_sample_playback_name Sample playback name, text
|
|
# This option sends the raw I/Q samples to another program using a loopback device (Linux) or
|
|
# a Virtual Audio Cable (Windows). The sample rate is the same as the hardware sample rate.
|
|
# Read the samples from the loopback device with another program.
|
|
lin_sample_playback_name = ""
|
|
#lin_sample_playback_name = "hw:Loopback,0"
|
|
|
|
## win_sample_playback_name Sample playback name, text
|
|
# This option sends the raw I/Q samples to another program using a loopback device (Linux) or
|
|
# a Virtual Audio Cable (Windows). The sample rate is the same as the hardware sample rate.
|
|
# Read the samples from the loopback device with another program.
|
|
win_sample_playback_name = ""
|
|
#win_sample_playback_name = "COM6"
|
|
|
|
sample_playback_name = ""
|
|
|
|
# When you use the microphone input, the mic_channel_I and Q are the two capture
|
|
# microphone channels. Quisk uses a monophonic mic, so audio is taken from the I
|
|
# channel, and the Q channel is (currently) ignored. It is OK to set the same
|
|
# channel number for both, and this is necessary for a USB mono mic. The mic sample rate
|
|
# should be 48000 to enable digital modes and the sound recorder to work, but 8000 can be used.
|
|
# Mic samples can be sent to an Ethernet device (use tx_ip and name_of_mic_play = "")
|
|
# or to a sound card (use name_of_mic_play="hw:1" or other device).
|
|
#
|
|
# If mic samples are sent to a sound card for Tx, the samples are tuned to the audio
|
|
# transmit frequency, and are set to zero unless the key is down. You must set both
|
|
# microphone_name and name_of_mic_play even for CW. For softrock hardware, you usually
|
|
# capture radio samples and play Tx audio on one soundcard; and capture the mic and play radio
|
|
# sound on the other sound card at 48000 sps. For example:
|
|
# name_of_sound_capt = "hw:0" # high quality sound card at 48, 96, or 192 ksps
|
|
# name_of_sound_play = "hw:1" # lower quality sound card at 48 ksps
|
|
# microphone_name = name_of_sound_play
|
|
# name_of_mic_play = name_of_sound_capt
|
|
|
|
## lin_name_of_sound_play Play radio sound, text
|
|
# Name of device to play demodulated radio audio.
|
|
lin_name_of_sound_play = "hw:0"
|
|
|
|
## win_name_of_sound_play Play radio sound, text
|
|
# Name of device to play demodulated radio audio.
|
|
win_name_of_sound_play = "Primary"
|
|
|
|
## lin_name_of_sound_capt Capture audio samples, text
|
|
# Name of device to capture samples from an audio device.
|
|
lin_name_of_sound_capt = "hw:0"
|
|
|
|
## win_name_of_sound_capt Capture audio samples, text
|
|
# Name of device to capture samples from an audio device.
|
|
win_name_of_sound_capt = "Primary"
|
|
|
|
## sample_rate Sample rate, integer
|
|
# The sample rate when capturing samples from a sound card.
|
|
#sample_rate = 48000
|
|
#sample_rate = 96000
|
|
#sample_rate = 192000
|
|
|
|
# Microphone capture:
|
|
## lin_microphone_name Microphone name, text
|
|
# Name of microphone capture device (or "hw:1")
|
|
lin_microphone_name = ""
|
|
|
|
## win_microphone_name Microphone name, text
|
|
# Name of microphone capture device (or "hw:1")
|
|
win_microphone_name = ""
|
|
|
|
microphone_name = ''
|
|
|
|
## mic_sample_rate Mic sample rate, integer choice
|
|
# Microphone capture sample rate in Hertz, should be 48000, can be 8000
|
|
mic_sample_rate = 48000
|
|
#mic_sample_rate = 8000
|
|
|
|
## mic_channel_I Mic channel I, integer
|
|
# Soundcard index of mic capture audio channel
|
|
mic_channel_I = 0
|
|
|
|
## mic_channel_Q Mic channel Q, integer
|
|
# Soundcard index of ignored capture channel
|
|
mic_channel_Q = 0
|
|
|
|
## lin_name_of_mic_play Mic play name, text
|
|
# Tx audio samples sent to soundcard (SoftRock).
|
|
# Name of play device if Tx audio I/Q is sent to a sound card.
|
|
lin_name_of_mic_play = ""
|
|
|
|
## win_name_of_mic_play Mic play name, text
|
|
# Tx audio samples sent to soundcard (SoftRock).
|
|
# Name of play device if Tx audio I/Q is sent to a sound card.
|
|
win_name_of_mic_play = ""
|
|
|
|
name_of_mic_play = ""
|
|
|
|
## mic_playback_rate Mic playback rate, integer
|
|
# Playback rate must be a multiple 1, 2, ... of mic_sample_rate
|
|
mic_playback_rate = 48000
|
|
#mic_playback_rate = 24000
|
|
#mic_playback_rate = 96000
|
|
#mic_playback_rate = 192000
|
|
|
|
## mic_play_chan_I Mic play channel I, integer
|
|
# Soundcard index of Tx audio I play channel
|
|
mic_play_chan_I = 0
|
|
#mic_play_chan_I = 1
|
|
|
|
## mic_play_chan_Q Mic play channel Q, integer
|
|
# Soundcard index of Tx audio Q play channel
|
|
mic_play_chan_Q = 1
|
|
#mic_play_chan_Q = 0
|
|
|
|
## lin_digital_input_name Digital input name, text
|
|
# Input audio from an external program for use with digital modes. The input must be
|
|
# stereo at 48000 sps, and you must set mic_sample_rate to 48000 also.
|
|
lin_digital_input_name = ""
|
|
|
|
## win_digital_input_name Digital input name, text
|
|
# Input audio from an external program for use with digital modes. The input must be
|
|
# stereo at 48000 sps, and you must set mic_sample_rate to 48000 also.
|
|
win_digital_input_name = ""
|
|
|
|
digital_input_name = ""
|
|
|
|
## lin_digital_output_name Digital output name, text
|
|
# Output audio to an external program for use with digital modes. The output is
|
|
# stereo at the same sample rate as the radio sound playback.
|
|
lin_digital_output_name = ""
|
|
|
|
## win_digital_output_name Digital output name, text
|
|
# Output audio to an external program for use with digital modes. The output is
|
|
# stereo at the same sample rate as the radio sound playback.
|
|
win_digital_output_name = ""
|
|
|
|
digital_output_name = ""
|
|
|
|
## lin_digital_rx1_name Digital sub-receiver 1 output name, text
|
|
# Output audio to an external program for use with digital modes.
|
|
lin_digital_rx1_name = ""
|
|
|
|
## win_digital_rx1_name Digital sub-receiver 1 output name, text
|
|
# Output audio to an external program for use with digital modes.
|
|
win_digital_rx1_name = ""
|
|
|
|
digital_rx1_name = ""
|
|
|
|
## digital_output_level Digital output level, number
|
|
# This is the volume control 0.0 to 1.0 for digital playback to fldigi, etc.
|
|
# Changes are immediate (no need to restart).
|
|
digital_output_level = 0.7
|
|
|
|
# Sound card names:
|
|
#
|
|
# In PortAudio, soundcards have an index number 0, 1, 2, ... and a name.
|
|
# The name can be something like "HDA NVidia: AD198x Analog (hw:0,0)" or
|
|
# "surround41". In Quisk, all PortAudio device names start with "portaudio".
|
|
# A device name like "portaudio#6" directly specifies the index. A name like
|
|
# "portaudio:text" means to search for "text" in all available devices. And
|
|
# there is a default device "portaudiodefault". So these portaudio names are useful:
|
|
#name_of_sound_capt = "portaudio:(hw:0,0)" # First sound card
|
|
#name_of_sound_capt = "portaudio:(hw:1,0)" # Second sound card, etc.
|
|
#name_of_sound_capt = "portaudio#1" # Directly specified index
|
|
#name_of_sound_capt = "portaudiodefault" # May give poor performance on capture
|
|
#
|
|
# In ALSA, soundcards have these names. The "hw" devices are the raw
|
|
# hardware devices, and should be used for soundcard capture.
|
|
#name_of_sound_capt = "hw:0" # First sound card
|
|
#name_of_sound_capt = "hw:1" # Second sound card, etc.
|
|
#name_of_sound_capt = "plughw"
|
|
#name_of_sound_capt = "plughw:1"
|
|
#name_of_sound_capt = "default"
|
|
#
|
|
# It is usually best to use ALSA names because they provide minimum latency. But
|
|
# you may need to use PulseAudio to connect to other programs such as wsjt-x.
|
|
#
|
|
# Pulseaudio support was added by Philip G. Lee. Many thanks!
|
|
# More pulse audio support was added by Eric Thornton, KM4DSJ. Many thanks!
|
|
#
|
|
# For PulseAudio devices, use the name "pulse:name" and connect the streams
|
|
# to your hardware devices using a PulseAudio control program. The name "pulse"
|
|
# alone refers to the "default" device. The PulseAudio names are quite long;
|
|
# for example "alsa_output.pci-0000_00_1b.0.analog-stereo". Look on the screen
|
|
# Config/Sound to see the device names. There is a description, a PulseAudio name,
|
|
# and for ALSA devices, the ALSA name. An example is:
|
|
#
|
|
# CM106 Like Sound Device Analog Stereo
|
|
# alsa_output.usb-0d8c_USB_Sound_Device-00-Device.analog-stereo
|
|
# USB Sound Device USB Audio (hw:1,0)
|
|
#
|
|
# Instead of the long PulseAudio name, you can enter a substring of any of
|
|
# these three strings.
|
|
#
|
|
# Use the default pulse device for radio sound:
|
|
#name_of_sound_play = "pulse"
|
|
# Use a PulseAudio name for radio sound:
|
|
#name_of_sound_play = "pulse:alsa_output.usb-0d8c_USB_Sound_Device-00-Device.analog-stereo"
|
|
# Abbreviate the PulseAudio name:
|
|
#name_of_sound_play = "pulse:alsa_output.usb"
|
|
# Another abbreviation:
|
|
#name_of_sound_play = "pulse:CM106"
|
|
#
|
|
# This controls whether the PulseAudio devices are shown in the device list.
|
|
# If you don't have PulseAudio, you must set this to False. Thanks to Simon, S54MI.
|
|
|
|
## lin_latency_millisecs Play latency msec, integer
|
|
# Play latency determines how many samples are in the radio sound play buffer.
|
|
# A larger number makes it less likely that you will run out of samples to play,
|
|
# but increases latency. It is OK to suffer a certain number of play buffer
|
|
# underruns in order to get lower latency.
|
|
lin_latency_millisecs = 150
|
|
#lin_latency_millisecs = 50
|
|
#lin_latency_millisecs = 100
|
|
#lin_latency_millisecs = 250
|
|
|
|
## win_latency_millisecs Play latency msec, integer
|
|
# Play latency determines how many samples are in the radio sound play buffer.
|
|
# A larger number makes it less likely that you will run out of samples to play,
|
|
# but increases latency. It is OK to suffer a certain number of play buffer
|
|
# underruns in order to get lower latency.
|
|
win_latency_millisecs = 150
|
|
#win_latency_millisecs = 50
|
|
#win_latency_millisecs = 100
|
|
#win_latency_millisecs = 250
|
|
|
|
latency_millisecs = 150
|
|
|
|
# If False, no list of PulseAudio devices is available.
|
|
# show_pulse_audio_devices Show PulseAudio, boolean
|
|
# This controls whether PulseAudio devices are shown in the list of sound devices.
|
|
show_pulse_audio_devices = True
|
|
#show_pulse_audio_devices = False
|
|
|
|
|
|
|
|
################ Options
|
|
## max_record_minutes Max minutes record time, number
|
|
# Quisk has record and playback buttons to save radio sound. If there is no more room for
|
|
# sound, the old sound is discarded and the most recent sound is retained. This controls
|
|
# the maximum time of sound storage in minutes for this recorded audio, and also the record
|
|
# time for the Tx Audio test screen. If you want to transmit recorded sound, then mic_sample_rate
|
|
# must equal playback_rate and both must be 48000.
|
|
max_record_minutes = 1.00
|
|
|
|
# Quisk can save radio sound and samples to files, and can play recorded sound. There is a button on the
|
|
# Config/Config screen to set the file names. You can set the initial names with these variables:
|
|
file_name_audio = ""
|
|
#file_name_audio = "/home/jim/tmp/qaudio.wav"
|
|
|
|
file_name_samples = ""
|
|
#file_name_samples = "C:/tmp/qsamples.wav"
|
|
# The file for playback must be 48 ksps, 16-bit, one channel (monophonic); the same as the mic input. When
|
|
# you play a file, the PTT button (if any) is pushed. There is a control to repeat the playback. This
|
|
# feature is intended to transmit a "CQ CQ" message, for example, during a contest.
|
|
file_name_playback = ""
|
|
#file_name_playback = "/home/jim/sounds/cqcq_contest.wav"
|
|
|
|
## do_repeater_offset Use repeater offset, boolean
|
|
# Quisk can implement the frequency shift needed for repeaters. If the repeater frequency
|
|
# is on the favorites screen, and you tune close (500 Hz) to that frequency in FM mode,
|
|
# then Quisk will shift the Tx frequency by the offset when transmitting.
|
|
# Quisk will also supply the CTCSS tone if one is entered.
|
|
# Note that no CTCSS tone is generated if no repeater offset is entered, but you can enter a small offset like 0.001.
|
|
# Your hardware file must define the method RepeaterOffset(self, offset=None).
|
|
do_repeater_offset = False
|
|
#do_repeater_offset = True
|
|
|
|
## correct_smeter S-meter correction in S units, number
|
|
# This converts from dB to S-units for the S-meter (it is in S-units).
|
|
correct_smeter = 15.5
|
|
#correct_smeter = 7.7
|
|
#correct_smeter = 21.6
|
|
|
|
## agc_max_gain Maximum AGC gain, number
|
|
# There is a button to turn AGC on or off,
|
|
# but AGC still limits the peak amplitude to avoid clipping even if it is off.
|
|
# Right click the AGC button to show the adjustment slider. If the slider is at maximum,
|
|
# all signals will have the same (maximum) amplitude. For lower values, weak signals
|
|
# will be somewhat less loud than strong signals; that is, some variation in signal
|
|
# amplitude remains.
|
|
# agc_max_gain controls the maximum AGC gain and thus the scale of the AGC slider control. If
|
|
# it is too high, all signals reach the same amplitude at much less than 100% slider.
|
|
# If it is too low, then all signals fail to have the same amplitude even at 100%. But
|
|
# the value is not critical, because you can adjust the slider a bit more.
|
|
agc_max_gain = 15000.0
|
|
#agc_max_gain = 10000.0
|
|
#agc_max_gain = 20000.0
|
|
|
|
## agc_release_time AGC release time in seconds, number
|
|
# This is the AGC release time in seconds. It must be greater than zero. It is the time
|
|
# constant for gain recovery after a strong signal disappears.
|
|
agc_release_time = 1.0
|
|
#agc_release_time = 2.0
|
|
#agc_release_time = 0.5
|
|
|
|
## freq_spacing Frequency rounding spacing, integer
|
|
# If freq_spacing is not zero, frequencies are rounded to the freq_base plus the
|
|
# freq_spacing; frequency = freq_base + N * freq_spacing. This is useful at
|
|
# VHF and higher when Quisk is used with a transverter.
|
|
# This option is incompatible with "Frequency round for SSB".
|
|
freq_spacing = 0
|
|
#freq_spacing = 25000
|
|
#freq_spacing = 15000
|
|
|
|
## freq_round_ssb Frequency round for SSB, integer
|
|
# If freq_round_ssb is not zero, when the left mouse button is clicked
|
|
# the frequency is rounded for voice modes but not for CW. Mouse wheel etc. are unaffected.
|
|
# This is useful for HF when many SSB, AM etc. stations are at multiples of 500 or 1000 Hertz.
|
|
# This option is incompatible with "Frequency rounding spacing".
|
|
freq_round_ssb = 0
|
|
#freq_round_ssb = 1000
|
|
|
|
## freq_base Frequency rounding base, integer
|
|
# If freq_spacing is not zero, frequencies are rounded to the freq_base plus the
|
|
# freq_spacing; frequency = freq_base + N * freq_spacing. This is useful at
|
|
# VHF and higher when Quisk is used with a transverter.
|
|
# This option is incompatible with "Frequency round for SSB".
|
|
freq_base = 0
|
|
#freq_base = 12500
|
|
|
|
## cwTone CW tone frequency in Hertz, integer
|
|
# This is the CW tone frequency in Hertz.
|
|
cwTone = 600
|
|
#cwTone = 400
|
|
#cwTone = 800
|
|
|
|
## invertSpectrum Invert the RF spectrum, integer choice
|
|
# If your mixing scheme inverts the RF spectrum, set this option to un-invert it.
|
|
invertSpectrum = 0 # Do not invert
|
|
#invertSpectrum = 1 # Invert spectrum
|
|
|
|
# This is a list of mixer settings. It only works for Linux; it has no effect in Windows.
|
|
# Use "amixer -c 1 contents" to get a list of mixer controls and their numid's for
|
|
# card 1 (or "-c 0" for card 0). Then make a list of (device_name, numid, value)
|
|
# for each control you need to set. For a decimal fraction, use a Python float; for example,
|
|
# use "1.0", not the integer "1".
|
|
#mixer_settings = [
|
|
# ("hw:1", 2, 0.80), # numid of microphone volume control, volume 0.0 to 1.0;
|
|
# ("hw:1", 1, 1) # numid of capture on/off control, turn on with 1;
|
|
# ]
|
|
|
|
## modulation_index FM modulation index, number
|
|
# For FM transmit, this is the modulation index.
|
|
modulation_index = 1.67
|
|
|
|
## pulse_audio_verbose_output Debug PulseAudio, integer choice
|
|
# Use 1 to turn on PulseAudio debug and status messages. This allows for debugging of both devices and performance.
|
|
pulse_audio_verbose_output = 0
|
|
#pulse_audio_verbose_output = 1
|
|
|
|
## favorites_file_path Path to favorites file, text
|
|
# The quisk config screen has a "favorites" tab where you can enter the frequencies and modes of
|
|
# stations. The data is stored in this file. If this is blank, the default is the file
|
|
# quisk_favorites.txt in the directory where your config file is located.
|
|
favorites_file_path = ''
|
|
|
|
## reverse_tx_sideband Reverse Tx sideband, integer
|
|
# Set to 1 if you want to reverse the sideband when transmitting.
|
|
# For example, to receive on LSB but transmit on USB. This may be necessary for satellite operation
|
|
# depending on the mixing scheme.
|
|
# Changes are immediate (no need to restart).
|
|
reverse_tx_sideband = 0
|
|
#reverse_tx_sideband = 1
|
|
|
|
## dc_remove_bw DC remove bandwidth, integer
|
|
# This is the 3 dB bandwidth of the filter centered at zero Hertz that is used to remove DC bias.
|
|
# Choose a bandwidth that suppresses DC and low frequency noise.
|
|
# Enter 1 to select a different filter based on block removal.
|
|
# Enter zero to disable the filter.
|
|
# Changes are immediate (no need to restart).
|
|
#dc_remove_bw = 0
|
|
#dc_remove_bw = 1
|
|
#dc_remove_bw = 20
|
|
#dc_remove_bw = 50
|
|
dc_remove_bw = 100
|
|
#dc_remove_bw = 200
|
|
#dc_remove_bw = 400
|
|
|
|
|
|
|
|
|
|
################ Remote
|
|
# DX cluster telent login data, thanks to DJ4CM. Must have station_display_lines > 0.
|
|
## dxClHost Dx cluster host name, text
|
|
# The Dx cluster options log into a Dx cluster server, and put station information
|
|
# on the station window under the graph and waterfall screens.
|
|
# dxClHost is the telnet host name.
|
|
dxClHost = ''
|
|
#dxClHost = 'example.host.net'
|
|
|
|
## dxClPort Dx cluster port number, integer
|
|
# The Dx cluster options log into a Dx cluster server, and put station information
|
|
# on the station window under the graph and waterfall screens.
|
|
# dxClPort is the telnet port number.
|
|
dxClPort = 7373
|
|
|
|
## user_call_sign Call sign for Dx cluster, text
|
|
# The Dx cluster options log into a Dx cluster server, and put station information
|
|
# on the station window under the graph and waterfall screens.
|
|
# user_call_sign is your call sign which may be needed for login.
|
|
user_call_sign = ''
|
|
|
|
## dxClPassword Password for Dx cluster, text
|
|
# The Dx cluster options log into a Dx cluster server, and put station information
|
|
# on the station window under the graph and waterfall screens.
|
|
# dxClPassword is the telnet password for the server.
|
|
dxClPassword = ''
|
|
#dxClPassword = 'getsomedx'
|
|
|
|
## dxClExpireTime Dx cluster expire minutes, integer
|
|
# The Dx cluster options log into a Dx cluster server, and put station information
|
|
# on the station window under the graph and waterfall screens.
|
|
# dxClExpireTime is the time in minutes until DX Cluster entries are removed.
|
|
dxClExpireTime = 20
|
|
|
|
## IQ_Server_IP Pulse server IP address, text
|
|
#IP Adddress for remote PulseAudio IQ server.
|
|
IQ_Server_IP = ""
|
|
|
|
## hamlib_ip IP address for Hamlib Rig 2, text
|
|
# You can control Quisk from Hamlib. Set the Hamlib rig to 2 and the device for rig 2 to
|
|
# localhost:4575. Or choose a different name and port here. Set the same name and port
|
|
# in the controlling program.
|
|
# hamlib_ip is the IP name or address.
|
|
hamlib_ip = "localhost"
|
|
|
|
## hamlib_port IP port for Hamlib, integer
|
|
# You can control Quisk from Hamlib. For direct control, set the external program to rig 2
|
|
# "Hamlib NET rigctl", and set the Quisk hamlib port to 4532. To use the rigctld program to control
|
|
# Quisk, set the Quisk hamlib port to 4575. To turn off Hamlib control, set the Quisk port to zero.
|
|
#hamlib_port = 4575
|
|
hamlib_port = 4532
|
|
#hamlib_port = 0
|
|
|
|
## digital_xmlrpc_url URL for control by XML-RPC, text
|
|
# This option is used by the digital modes that send audio to an external
|
|
# program, and receive audio to transmit. Set Fldigi to upper sideband, XML-RPC control.
|
|
digital_xmlrpc_url = "http://localhost:7362"
|
|
#digital_xmlrpc_url = ""
|
|
|
|
## lin_hamlib_com1_name CAT serial port name, text
|
|
# Enter a name to create a serial port so that an external program like N1MM+ or WSJT-X can
|
|
# control Quisk. Then enter that name into the other program and specify a radio of type "Flex". This is addition to the
|
|
# "Hamlib NET rigctl" mechanism which is based on a network connection. Leave this blank
|
|
# to turn off the serial port. The port settings are 9600 baud, 8 bits of data, no parity and one stop bit,
|
|
# although other settings are OK too.
|
|
# On Linux, the serial port names are of the form "/tmp/QuiskTTYx"
|
|
# where "x" is 0, 1, 2, etc. Quisk will create the serial port when it starts.
|
|
lin_hamlib_com1_name = ""
|
|
#lin_hamlib_com1_name = "/tmp/QuiskTTY0"
|
|
|
|
## lin_hamlib_com2_name CAT serial-2 name, text
|
|
# This is a second serial port for external control of Quisk. Use a different serial port name.
|
|
lin_hamlib_com2_name = ""
|
|
#lin_hamlib_com2_name = "/tmp/QuiskTTY1"
|
|
|
|
## win_hamlib_com1_name CAT serial port name, text
|
|
# Enter the name of the serial port that Quisk uses to connect to an external program like N1MM+ or WSJT-X.
|
|
# You must first create a pair of virtual serial ports with a program like vspMgr or HHD Software.
|
|
# Then enter the second name into the other program and specify a radio of type "Flex". This control method is in addition to the
|
|
# "Hamlib NET rigctl" mechanism which is based on a network connection. Leave this blank
|
|
# to turn off the serial port. The port settings are 9600 baud, 8 bits of data, no parity and one stop bit.
|
|
win_hamlib_com1_name = ""
|
|
#win_hamlib_com1_name = "COM5"
|
|
#win_hamlib_com1_name = "COM6"
|
|
|
|
## win_hamlib_com2_name CAT serial-2 name, text
|
|
# This is a second serial port for external control of Quisk. Use a different serial port pair.
|
|
win_hamlib_com2_name = ""
|
|
#win_hamlib_com2_name = "COM15"
|
|
#win_hamlib_com2_name = "COM16"
|
|
|
|
|
|
hamlib_com1_name = ""
|
|
hamlib_com2_name = ""
|
|
|
|
|
|
################ Keys
|
|
## hot_key_ptt1 PTT Key 1, keycode
|
|
# Set a keyboard shortcut that will press the PTT button.
|
|
# For a regular key, use the ord() of the key. For example, ord('a') or ord('b'). For the space bar
|
|
# use ord(' '). Then restart Quisk.
|
|
# If you do not want a hot key, set this to None.
|
|
# Do not choose a key that interferes with other features
|
|
# on your system such as system menus.
|
|
hot_key_ptt1 = None
|
|
#hot_key_ptt1 = ord(' ')
|
|
#hot_key_ptt1 = ord('z')
|
|
#hot_key_ptt1 = ord('a')
|
|
#hot_key_ptt1 = wx.WXK_F5
|
|
|
|
## hot_key_ptt2 PTT Key 2, keycode
|
|
# If the Control or Shift key must be pressed too, set that key modifier here.
|
|
# Otherwise, set NORMAL here.
|
|
# For example, if you want control-A, set CTRL in "PTT Key 2", and ord('a') in "PTT Key 1".
|
|
hot_key_ptt2 = wx.ACCEL_NORMAL
|
|
#hot_key_ptt2 = wx.ACCEL_CTRL
|
|
#hot_key_ptt2 = wx.ACCEL_SHIFT
|
|
#hot_key_ptt2 = wx.ACCEL_CTRL | wx.ACCEL_SHIFT
|
|
#hot_key_ptt2 = wx.ACCEL_ALT
|
|
|
|
## hot_key_ptt_toggle PTT Key Toggle, boolean
|
|
# Set to True if you want PTT to remain on when you release the key. A second key press will
|
|
# then release PTT. This is toggle mode. If False, you must keep pressing the key, and releasing
|
|
# it will release PTT.
|
|
# Changes are immediate (no need to restart).
|
|
hot_key_ptt_toggle = False
|
|
#hot_key_ptt_toggle = True
|
|
|
|
## hot_key_ptt_if_hidden PTT Key if Hidden, boolean
|
|
# Set to True if you want PTT to be active when the Quisk window is not visible.
|
|
# Otherwise, the Quisk window must be active and on top.
|
|
hot_key_ptt_if_hidden = False
|
|
#hot_key_ptt_if_hidden = True
|
|
|
|
|
|
|
|
|
|
################ Windows
|
|
# Station info display configuration, thanks to DJ4CM. This displays a window of station names
|
|
# below the graph frequency (X axis).
|
|
|
|
## station_display_lines Number of station lines, integer
|
|
# The number of station info display lines below the graph X axis.
|
|
station_display_lines = 1
|
|
#station_display_lines = 0
|
|
#station_display_lines = 3
|
|
|
|
## display_fraction Display fraction, number
|
|
# This is the fraction of spectrum to display from zero to one. It causes the edges
|
|
# of the display to be suppressed. For example, 0.85 displays the central 85% of the spectrum.
|
|
display_fraction = 1.00
|
|
|
|
## default_screen Startup screen, text choice
|
|
# Select the default screen when Quisk starts.
|
|
default_screen = 'Graph'
|
|
#default_screen = 'WFall'
|
|
#default_screen = 'Config'
|
|
|
|
## graph_width Startup graph width, number
|
|
# The width of the graph data as a fraction of the total screen size. This
|
|
# controls the width of the Quisk window, but
|
|
# will be adjusted by Quisk to accommodate preferred FFT sizes.
|
|
# It can not be made too small because
|
|
# of the space needed for all the buttons.
|
|
graph_width = 0.8
|
|
|
|
## window_width Window width pixels, integer
|
|
# The use of startup graph width provides an optimal size for PC screens. But when running
|
|
# full screen, for example, on a tablet screen or a dedicated display, greater control
|
|
# is required. These options exactly set the Quisk window geometry. When window pixel width
|
|
# is used, graph width is ignored. You may need to reduce button_font_size. Use -1
|
|
# to ignore this feature, and use graph width.
|
|
window_width = -1
|
|
#window_width = 640
|
|
|
|
## window_height Window height pixels, integer
|
|
# The use of startup graph width provides an optimal size for PC screens. But when running
|
|
# full screen, for example, on a tablet screen or a dedicated display, greater control
|
|
# is required. These options exactly set the Quisk window geometry. When window pixel width
|
|
# is used, graph width is ignored. You may need to reduce button_font_size. Use -1
|
|
# to ignore this feature, and use graph width.
|
|
window_height = -1
|
|
#window_height = 480
|
|
|
|
## window_posX Window X position, integer
|
|
# The use of startup graph width provides an optimal size for PC screens. But when running
|
|
# full screen, for example, on a tablet screen or a dedicated display, greater control
|
|
# is required. These options exactly set the Quisk window geometry. When window pixel width
|
|
# is used, graph width is ignored. You may need to reduce button_font_size. Use -1
|
|
# to ignore this feature, and use graph width.
|
|
window_posX = -1
|
|
#window_posX = 0
|
|
|
|
## window_posY Window Y position, integer
|
|
# The use of startup graph width provides an optimal size for PC screens. But when running
|
|
# full screen, for example, on a tablet screen or a dedicated display, greater control
|
|
# is required. These options exactly set the Quisk window geometry. When window pixel width
|
|
# is used, graph width is ignored. You may need to reduce button_font_size. Use -1
|
|
# to ignore this feature, and use graph width.
|
|
window_posY = -1
|
|
#window_posY = 0
|
|
|
|
## button_layout Button layout, text choice
|
|
# This option controls how many buttons are displayed on the screen. The large screen
|
|
# layout is meant for a PC. The small screen layout is meant for small touch screens, and
|
|
# small screens used in embedded systems.
|
|
button_layout = 'Large screen'
|
|
#button_layout = 'Small screen'
|
|
|
|
|
|
# These are the initial values for the Y-scale and Y-zero sliders for each screen.
|
|
# The sliders go from zero to 160.
|
|
graph_y_scale = 100
|
|
graph_y_zero = 0
|
|
waterfall_y_scale = 80 # Initial value; new values are saved for each band
|
|
waterfall_y_zero = 40 # Initial value; new values are saved for each band
|
|
waterfall_graph_y_scale = 100
|
|
waterfall_graph_y_zero = 60
|
|
scope_y_scale = 80
|
|
scope_y_zero = 0 # Currently doesn't do anything
|
|
filter_y_scale = 90
|
|
filter_y_zero = 0
|
|
|
|
# Select the way the waterfall screen scrolls:
|
|
# waterfall_scroll_mode = 0 # scroll at a constant rate.
|
|
waterfall_scroll_mode = 1 # scroll faster at the top so that a new signal appears sooner.
|
|
|
|
# Select the initial size in pixels (minimum 1) of the graph at the top of the waterfall.
|
|
waterfall_graph_size = 80
|
|
|
|
# Quisk saves radio settings in a settings file. The default directory is the same as the config
|
|
# file, and the file name is quisk_settings.json. You can set a different name here. If you dual
|
|
# boot Windows and Linux, you can set the same path in your Windows and Linux config files, so that
|
|
# settings are shared. Even if Windows and Linux settings are shared, the sound device names and a
|
|
# few other settings are kept separate.
|
|
settings_file_path = ''
|
|
#settings_file_path = /path/to/my/file/quisk_settings.json
|
|
|
|
|
|
|
|
|
|
################ Timing
|
|
|
|
## lin_data_poll_usec Hardware poll usecs, integer
|
|
# Quisk polls the hardware for samples at intervals. This is the poll time in microseconds.
|
|
# A lower time reduces latency. A higher time is less taxing on the hardware.
|
|
#lin_data_poll_usec = 5000
|
|
#lin_data_poll_usec = 10000
|
|
#lin_data_poll_usec = 15000
|
|
#lin_data_poll_usec = 20000
|
|
|
|
## win_data_poll_usec Hardware poll usecs, integer
|
|
# Quisk polls the hardware for samples at intervals. This is the poll time in microseconds.
|
|
# A lower time reduces latency. A higher time is less taxing on the hardware.
|
|
#win_data_poll_usec = 15000
|
|
#win_data_poll_usec = 5000
|
|
#win_data_poll_usec = 10000
|
|
#win_data_poll_usec = 20000
|
|
|
|
if sys.platform == "win32":
|
|
data_poll_usec = 20000 # poll time in microseconds
|
|
else:
|
|
data_poll_usec = 5000 # poll time in microseconds
|
|
|
|
## keyupDelay Keyup delay msecs, integer
|
|
# For the Hermes protocol including the Hermes-Lite2, this is the key-up hang time,
|
|
# the time in milliseconds 0 to 1023 to hold the T/R relay after the CW key goes up
|
|
# or the PTT button goes up. For all
|
|
# hardware, it adds a silent period to the audio after key up.
|
|
# A large key up delay may be needed to accomodate
|
|
# antenna switching or other requirements of your hardware.
|
|
# Changes are immediate (no need to restart).
|
|
keyupDelay = 23
|
|
|
|
## fft_size_multiplier FFT size multiplier, integer
|
|
# The fft_size is the width of the data on the screen (about 800 to
|
|
# 1200 pixels) times the fft_size_multiplier. Multiple FFTs are averaged
|
|
# together to achieve your graph refresh rate. If fft_size_multiplier is
|
|
# too small you will get many fft errors. You can specify fft_size_multiplier,
|
|
# or enter a large number (use 9999) to maximize it, or enter zero to let
|
|
# quisk calculate it for you.
|
|
# Your fft_size_multiplier should have many small factors. Avoid 7 and 13, and
|
|
# use 8 or 12 instead.
|
|
# If your hardware can change the decimation, there are further compilcations.
|
|
# The FFT size is fixed, and only the average count can change to adjust the
|
|
# refresh rate.
|
|
fft_size_multiplier = 0
|
|
|
|
## graph_refresh Graph refresh Hertz, integer
|
|
# The graph_refresh is the frequency at which the graph is updated,
|
|
# and should be about 5 to 10 Hertz. Higher rates require more processor power.
|
|
graph_refresh = 7
|
|
|
|
|
|
|
|
|
|
|
|
################ Controls
|
|
|
|
## graph_peak_hold_1 Graph peak hold 1, number
|
|
# This controls the speed of the graph peak hold for the two settings
|
|
# of the Graph button. Lower numbers give a longer time constant.
|
|
graph_peak_hold_1 = 0.25
|
|
|
|
## graph_peak_hold_2 Graph peak hold 2, number
|
|
# This controls the speed of the graph peak hold for the two settings
|
|
# of the Graph button. Lower numbers give a longer time constant.
|
|
graph_peak_hold_2 = 0.10
|
|
|
|
|
|
## use_sidetone Use sidetone, integer choice
|
|
# This controls whether Quisk will display a sidetone volume control "Sto",
|
|
# and whether Quisk will gererate a CW sidetone.
|
|
use_sidetone = 0
|
|
#use_sidetone = 1
|
|
|
|
## add_imd_button Add IMD button, integer choice
|
|
# If you want Quisk to add a button to generate a 2-tone IMD test signal,
|
|
# set this to 1.
|
|
add_imd_button = 0
|
|
#add_imd_button = 1
|
|
|
|
## add_extern_demod Add ext demod button, text
|
|
# If you want to write your own I/Q filter and demodulation module, set
|
|
# this to the name of the button to add, and change extdemod.c.
|
|
add_extern_demod = ""
|
|
#add_extern_demod = "WFM"
|
|
|
|
## add_fdx_button Add FDX button, integer choice
|
|
# If you want Quisk to add a full duplex button (transmit and receive at the
|
|
# same time), set this to 1.
|
|
add_fdx_button = 0
|
|
#add_fdx_button = 1
|
|
|
|
## add_freedv_button Add FreeDv button, integer choice
|
|
# These buttons add up to two additional mode buttons after CW, USB, etc.
|
|
# Set this to add the FDV mode button for digital voice:
|
|
add_freedv_button = 1
|
|
#add_freedv_button = 0
|
|
|
|
## freedv_tx_msg FreeDv Tx message, text
|
|
# For freedv, this is the text message to send.
|
|
freedv_tx_msg = ''
|
|
#freedv_tx_msg = 'N2XXX Jim, New Jersey, USA \n'
|
|
|
|
|
|
# This is the list of FreeDV modes and their index number. The starting mode is the first listed.
|
|
freedv_modes = (('Mode 1600', 0), ('Mode 700', 1), ('Mode 700B', 2),
|
|
# ('Mode 2400A', 3), ('Mode 2400B', 4), ('Mode 800XA', 5),
|
|
('Mode 700C', 6), ('Mode 700D', 7), ('Mode 2020', 8), ('Future9', 9), ('Future10', 10))
|
|
|
|
# These are the filter bandwidths for each mode. Quisk has built-in optimized filters
|
|
# for these values, but you can change them if you want.
|
|
FilterBwCW = (200, 400, 600, 1000, 1500, 3000)
|
|
FilterBwSSB = (2000, 2200, 2500, 2800, 3000, 3300)
|
|
FilterBwAM = (4000, 5000, 6000, 8000, 10000, 9000)
|
|
FilterBwFM = (8000, 10000, 12000, 16000, 18000, 20000)
|
|
FilterBwIMD = FilterBwSSB
|
|
FilterBwDGT = (200, 400, 1500, 3200, 4800, 10000)
|
|
FilterBwEXT = (8000, 10000, 12000, 15000, 17000, 20000)
|
|
FilterBwFDV = (1500, 2000, 3000, '', '', '')
|
|
|
|
# If your hardware file defines the method OnButtonPTT(self, event), then Quisk will
|
|
# display a PTT button you can press. The method must switch your hardware to
|
|
# transmit somehow, for example, by setting a serial port pin to high.
|
|
|
|
## spot_button_keys_tx Key Tx on Spot, boolean
|
|
# If you want the Spot button to key the transmitter immediately when you press it, set this option.
|
|
# Your hardware must have a working PTT button for this to work.
|
|
spot_button_keys_tx = True
|
|
#spot_button_keys_tx = False
|
|
|
|
|
|
|
|
# Thanks to Christof, DJ4CM, for button fonts.
|
|
################ Fonts
|
|
|
|
## button_font_size Button font size, integer
|
|
# If the Quisk screen is too wide or the buttons are too crowded, perhaps due to a low screen
|
|
# resolution, you can reduce the font sizes.
|
|
button_font_size = 10
|
|
#button_font_size = 9
|
|
#button_font_size = 8
|
|
|
|
## default_font_size Default font size, integer
|
|
# These control the font size on the named screen.
|
|
default_font_size = 12
|
|
|
|
## status_font_size Status font size, integer
|
|
# These control the font size on the named screen.
|
|
status_font_size = 14
|
|
|
|
## config_font_size Config font size, integer
|
|
# These control the font size on the named screen.
|
|
config_font_size = 14
|
|
|
|
## graph_font_size Graph font size, integer
|
|
# These control the font size on the named screen.
|
|
graph_font_size = 10
|
|
|
|
## graph_msg_font_size Graph message font size, integer
|
|
# These control the font size on the named screen.
|
|
graph_msg_font_size = 14
|
|
|
|
## favorites_font_size Favorites font size, integer
|
|
# These control the font size on the named screen.
|
|
favorites_font_size = 14
|
|
|
|
## lin_quisk_typeface Typeface, text
|
|
# This controls the typeface used in fonts. The objective is to choose an available font that
|
|
# offers good support for the Unicode characters used on buttons and windows.
|
|
#lin_quisk_typeface = ''
|
|
|
|
## win_quisk_typeface Typeface, text
|
|
# This controls the typeface used in fonts. The objective is to choose an available font that
|
|
# offers good support for the Unicode characters used on buttons and windows.
|
|
#win_quisk_typeface = 'Lucida Sans Unicode'
|
|
#win_quisk_typeface = 'Arial Unicode MS'
|
|
|
|
if sys.platform == "win32":
|
|
quisk_typeface = 'Lucida Sans Unicode'
|
|
#quisk_typeface = 'Arial Unicode MS'
|
|
else:
|
|
quisk_typeface = ''
|
|
|
|
## use_unicode_symbols Use Unicode symbols, boolean
|
|
# This controls whether the "U" unicode symbols or the "T" text symbols are used on buttons and windows.
|
|
# You can change the "U" and "T" symbols to anything you want in your config file.
|
|
use_unicode_symbols = True
|
|
#use_unicode_symbols = False
|
|
|
|
# These are the Unicode symbols used in the station window. Thanks to Christof, DJ4CM.
|
|
Usym_stat_fav = u"\u2605" # Symbol for favorites, a star
|
|
Usym_stat_mem = u"\u24C2" # Symbol for memory stations, an "M" in a circle
|
|
#Usym_stat_dx = u"\u2691" # Symbol for DX Cluster stations, a flag
|
|
Usym_stat_dx = u"\u25B2" # Symbol for DX Cluster stations, a Delta
|
|
# These are the text symbols used in the station window.
|
|
Tsym_stat_fav = 'F'
|
|
Tsym_stat_mem = 'M'
|
|
Tsym_stat_dx = 'Dx'
|
|
#
|
|
# These are the Unicode symbols to display on buttons. Thanks to Christof, DJ4CM.
|
|
Ubtn_text_range_dn = u"\u2B07" # Down band, left arrow
|
|
Ubtn_text_range_up = u"\u2B06" # Up band, right arrow
|
|
Ubtn_text_play = u"\u25BA" # Play button
|
|
Ubtn_text_rec = u"\u25CF" # Record button, a filled dot
|
|
Ubtn_text_file_rec = "File " + u"\u25CF" # Record to file
|
|
Ubtn_text_file_play = "File " + u"\u25BA" # Play from file
|
|
Ubtn_text_fav_add = u"\u2605" + u"\u2191" # Add to favorites
|
|
Ubtn_text_fav_recall = u"\u2605" + u"\u2193" # Jump to favorites screen
|
|
Ubtn_text_mem_add = u"\u24C2" + u"\u2191" # Add to memory
|
|
Ubtn_text_mem_next = u"\u24C2" + u"\u27B2" # Next memory
|
|
Ubtn_text_mem_del = u"\u24C2" + u"\u2613" # Delete from memory
|
|
# These are the text symbols to display on buttons.
|
|
Tbtn_text_range_dn = "Dn"
|
|
Tbtn_text_range_up = "Up"
|
|
Tbtn_text_play = "Tmp Play"
|
|
Tbtn_text_rec = "Tmp Rec"
|
|
Tbtn_text_file_rec = "File Rec"
|
|
Tbtn_text_file_play = "File Play"
|
|
Tbtn_text_fav_add = ">Fav"
|
|
Tbtn_text_fav_recall = "Fav"
|
|
Tbtn_text_mem_add = "Save"
|
|
Tbtn_text_mem_next = "Next"
|
|
Tbtn_text_mem_del = "Del"
|
|
|
|
## decorate_buttons Decorate buttons, boolean
|
|
# This controls whether to add the button decorations that mark cycle and adjust buttons.
|
|
decorate_buttons = True
|
|
#decorate_buttons = False
|
|
|
|
btn_text_cycle = u"\u21B7" # Character to display on multi-push buttons
|
|
btn_text_cycle_small = u"\u2193" # Smaller version when there is little space
|
|
btn_text_switch = u"\u21C4" # Character to switch left-right
|
|
|
|
## color_scheme Color scheme, text choice
|
|
# This controls the color scheme used by Quisk. The default color scheme is A, and you can change this scheme
|
|
# in your config file. Other color schemes are available here.
|
|
color_scheme = 'A'
|
|
#color_scheme = 'B'
|
|
#color_scheme = 'C'
|
|
|
|
## waterfall_palette Waterfall colors, text choice
|
|
# This controls the colors used in the waterfall. The default color scheme is A, and you can change this scheme
|
|
# in your config file. Other color schemes are available here.
|
|
waterfall_palette = 'A'
|
|
#waterfall_palette = 'B'
|
|
#waterfall_palette = 'C'
|
|
|
|
|
|
|
|
|
|
################ Colors
|
|
# Thanks to Steve Murphy, KB8RWQ for the patch adding additional color control.
|
|
# Thanks to Christof, DJ4CM for the patch adding additional color control.
|
|
# Define colors used by all widgets in wxPython colour format.
|
|
# This is the default color scheme, color scheme A. You can change these colors in your config file:
|
|
color_bg = 'light steel blue' # Lower screen background
|
|
color_bg_txt = 'black' # Lower screen text color
|
|
color_graph = 'lemonchiffon1' # Graph background
|
|
color_config2 = 'lemonchiffon3' # color in tab row of config screen
|
|
color_gl = 'grey' # Lines on the graph
|
|
color_graphticks = 'black' # Graph ticks
|
|
color_graphline = '#005500' # graph data line color
|
|
color_graphlabels = '#555555' # graph label color
|
|
color_btn = 'steelblue2' # button color
|
|
color_check_btn = 'yellow2' # color of a check button when it is checked
|
|
color_cycle_btn = 'goldenrod3' # color of a cycle button when it is checked
|
|
color_adjust_btn = 'orange3' # color of an adjustable button when it is checked
|
|
color_test = 'hot pink' # color of a button used for test (turn off for tx)
|
|
color_freq = 'lightcyan1' # background color of frequency and s-meter
|
|
color_freq_txt = 'black' # text color of frequency display
|
|
color_entry = color_freq # frequency entry box
|
|
color_entry_txt = 'black' # text color of entry box
|
|
color_enable = 'black' # text color for an enabled button
|
|
color_disable = 'white' # text color for a disabled button
|
|
color_popchoice = 'maroon' # text color for button that pops up a row of buttons
|
|
color_bandwidth = 'lemonchiffon3' # color for bandwidth display; thanks to WB4JFI
|
|
color_txline = 'red' # vertical line color for tx in graph
|
|
color_rxline = 'green' # vertical line color for rx in graph
|
|
color_graph_msg_fg = 'black' # text messages on the graph screen
|
|
color_graph_msg_bg = 'lemonchiffon2' # background of text messages on the graph screen
|
|
|
|
# This color scheme B, a dark color scheme designed by Steve Murphy, KB8RWQ.
|
|
# Additional colors added by N2ADR.
|
|
color_scheme_B = {
|
|
'color_bg' : '#111111',
|
|
'color_bg_txt' : 'white',
|
|
'color_graph' : '#111111',
|
|
'color_config2' : '#111111',
|
|
'color_gl' : '#555555',
|
|
'color_graphticks' : '#DDDDDD',
|
|
'color_graphline' : '#00AA00',
|
|
'color_graphlabels' : '#FFFFFF',
|
|
'color_btn' : '#666666',
|
|
'color_check_btn' : '#996699',
|
|
'color_cycle_btn' : '#666699',
|
|
'color_adjust_btn' : '#669999',
|
|
'color_test' : 'hot pink',
|
|
'color_freq' : '#333333',
|
|
'color_freq_txt' : 'white',
|
|
'color_entry' : '#333333',
|
|
'color_entry_txt' : 'white',
|
|
'color_enable' : 'white',
|
|
'color_disable' : 'black',
|
|
'color_popchoice' : 'maroon',
|
|
'color_bandwidth' : '#333333',
|
|
'color_txline' : 'red',
|
|
'color_rxline' : 'green',
|
|
'color_graph_msg_fg' : 'white',
|
|
'color_graph_msg_bg' : '#111111',
|
|
}
|
|
|
|
# This is color scheme C:
|
|
#######################################################################################
|
|
#
|
|
# Color scheme designed by Sergio, IK8HTM. 04/06/2016
|
|
# '#red red green green blue blue' x00 to xFF
|
|
# '#FFFFFF' = white
|
|
# '#000000' = black
|
|
#
|
|
#######################################################################################
|
|
color_scheme_C = {
|
|
'color_bg' : '#123456',
|
|
'color_bg_txt' : '#FFFFFF',
|
|
'color_graph' : 'lightcyan3',
|
|
'color_config2' : '#0000FF',
|
|
'color_gl' : '#555555',
|
|
'color_graphticks' : '#DDDDDD',
|
|
'color_graphline' : '#00AA00',
|
|
'color_graphlabels' : '#000000',
|
|
'color_btn' : '#223344',
|
|
'color_check_btn' : '#A07315',
|
|
'color_cycle_btn' : '#0031C4',
|
|
'color_adjust_btn' : '#669999',
|
|
'color_test' : '#E73EE7',
|
|
'color_freq' : '#333333',
|
|
'color_freq_txt' : '#FEF80A',
|
|
'color_entry' : '#333333',
|
|
'color_entry_txt' : '#FEF80A',
|
|
'color_enable' : '#FFFFFF',
|
|
'color_disable' : '#000000',
|
|
'color_popchoice' : '#D76B00',
|
|
'color_bandwidth' : 'lemonchiffon1',
|
|
'color_txline' : '#FF0000',
|
|
'color_rxline' : '#3CC918',
|
|
'color_graph_msg_fg' : '#000000',
|
|
'color_graph_msg_bg' : 'lemonchiffon2',
|
|
}
|
|
#############################################################################################
|
|
|
|
|
|
# These are the palettes for the waterfall. The one used is named waterfallPallette,
|
|
# so to use a different one, overwrite this name in your configuration file.
|
|
waterfallPalette = (
|
|
( 0, 0, 0, 0),
|
|
( 36, 85, 0, 255),
|
|
( 73, 153, 0, 255),
|
|
(109, 255, 0, 128),
|
|
(146, 255, 119, 0),
|
|
(182, 85, 255, 100),
|
|
(219, 255, 255, 0),
|
|
(255, 255, 255, 255)
|
|
)
|
|
digipanWaterfallPalette = (
|
|
( 0, 0, 0, 0),
|
|
( 32, 0, 0, 62),
|
|
( 64, 0, 0, 126),
|
|
( 96, 145, 142, 96),
|
|
(128, 181, 184, 48),
|
|
(160, 223, 226, 105),
|
|
(192, 254, 254, 4),
|
|
(255, 255, 58, 0)
|
|
)
|
|
|
|
waterfallPaletteB = ( # from David Fainitski
|
|
(0, 0, 0, 0),
|
|
(13, 0, 14, 14),
|
|
(26, 0, 40, 40),
|
|
(39, 0, 73, 73),
|
|
(43, 0, 94, 94),
|
|
(56, 0, 115, 121),
|
|
(69, 0, 87, 190),
|
|
(72, 0, 110, 252),
|
|
(85, 0, 166, 252),
|
|
(98, 0, 216, 252),
|
|
(112, 0, 247, 234),
|
|
(125, 2, 255, 124),
|
|
(138, 5, 255, 64),
|
|
(151, 154, 255, 0),
|
|
(164, 219, 255, 0),
|
|
(177, 247, 250, 0),
|
|
(190, 254, 233, 0),
|
|
(214, 254, 185, 0),
|
|
(227, 255, 125, 0),
|
|
(241, 255, 59, 0),
|
|
(255, 255, 0, 0)
|
|
)
|
|
|
|
waterfallPaletteC = ( # from David Fainitski
|
|
(0, 0, 0, 0),
|
|
(32, 0, 25, 25),
|
|
(64, 6, 58, 41),
|
|
(96, 16, 78, 43),
|
|
(128, 29, 120, 41),
|
|
(160, 51, 144, 35),
|
|
(192, 116, 141, 43),
|
|
(224, 195, 198, 35),
|
|
(255, 245, 99, 3)
|
|
)
|
|
|
|
# This is the data used to draw colored lines on the frequency X axis to
|
|
# indicate CW and Phone sub-bands. You can make it anything you want.
|
|
# These are the colors used for sub-bands:
|
|
CW = '#FF4444' # General class CW
|
|
eCW = '#FF8888' # Extra class CW
|
|
Phone = '#4444FF' # General class phone
|
|
ePhone = '#8888FF' # Extra class phone
|
|
# ARRL band plan special frequencies
|
|
Data = '#FF9900'
|
|
DxData = '#CC6600'
|
|
RTTY = '#FF9900'
|
|
SSTV = '#FFFF00'
|
|
AM = '#00FF00'
|
|
Packet = '#00FFFF'
|
|
Beacons = '#66FF66'
|
|
Satellite = '#22AA88'
|
|
Repeater = '#AA00FF' # Repeater outputs
|
|
RepInput = '#AA88FF' # Repeater inputs
|
|
Simplex = '#00FF44'
|
|
Special = 'hot pink'
|
|
Other = '#888888'
|
|
# Colors start at the indicated frequency and continue until the
|
|
# next frequency. The special color "None" turns off color.
|
|
#
|
|
|
|
|
|
|
|
|
|
################ Bands
|
|
# Band plans vary by country, so they can be changed here.
|
|
# To change BandPlan in your config file, first remove any frequencies in the range
|
|
# you want to change; then add your frequencies; and then sort the list. Or you could just
|
|
# replace the whole list.
|
|
# These are the suppressed carrier frequencies for 60 meters
|
|
freq60 = (5330500, 5346500, 5357000, 5371500, 5403500)
|
|
# Band plan
|
|
BandPlan = [
|
|
# Test display of colors
|
|
#[ 0, CW], [ 50000, eCW], [ 100000, Phone], [ 150000, ePhone], [ 200000, Data], [ 250000, DxData], [ 300000, RTTY], [ 350000, SSTV],
|
|
#[ 400000, AM], [ 450000, Packet], [ 500000, Beacons], [ 550000, Satellite], [ 600000, Repeater], [ 650000, RepInput], [ 700000, Simplex],
|
|
#[ 750000, Other], [ 800000, Special], [ 850000, None],
|
|
# 137k
|
|
[ 130000, Data],
|
|
[ 150000, None],
|
|
# 500k
|
|
[ 490000, Data],
|
|
[ 510000, None],
|
|
# 160 meters
|
|
[ 1800000, Data],
|
|
[ 1809000, Other],
|
|
[ 1811000, CW],
|
|
[ 1843000, Phone],
|
|
[ 1908000, Other],
|
|
[ 1912000, Phone],
|
|
[ 1995000, Other],
|
|
[ 2000000, None],
|
|
# 80 meters
|
|
[ 3500000, eCW],
|
|
[ 3525000, CW],
|
|
[ 3570000, Data],
|
|
[ 3589000, DxData],
|
|
[ 3591000, Data],
|
|
[ 3600000, ePhone],
|
|
[ 3790000, Other],
|
|
[ 3800000, Phone],
|
|
[ 3844000, SSTV],
|
|
[ 3846000, Phone],
|
|
[ 3880000, AM],
|
|
[ 3890000, Phone],
|
|
[ 4000000, None],
|
|
# 60 meters
|
|
[ freq60[0], Phone],
|
|
[ freq60[0] + 2800, None],
|
|
[ freq60[1], Phone],
|
|
[ freq60[1] + 2800, None],
|
|
[ freq60[2], Phone],
|
|
[ freq60[2] + 2800, None],
|
|
[ freq60[3], Phone],
|
|
[ freq60[3] + 2800, None],
|
|
[ freq60[4], Phone],
|
|
[ freq60[4] + 2800, None],
|
|
# 40 meters
|
|
[ 7000000, eCW],
|
|
[ 7025000, CW],
|
|
[ 7039000, DxData],
|
|
[ 7041000, CW],
|
|
[ 7080000, Data],
|
|
[ 7125000, ePhone],
|
|
[ 7170000, SSTV],
|
|
[ 7172000, ePhone],
|
|
[ 7175000, Phone],
|
|
[ 7285000, AM],
|
|
[ 7295000, Phone],
|
|
[ 7300000, None],
|
|
# 30 meters
|
|
[10100000, CW],
|
|
[10130000, RTTY],
|
|
[10140000, Packet],
|
|
[10150000, None],
|
|
# 20 meters
|
|
[14000000, eCW],
|
|
[14025000, CW],
|
|
[14070000, RTTY],
|
|
[14095000, Packet],
|
|
[14099500, Other],
|
|
[14100500, Packet],
|
|
[14112000, CW],
|
|
[14150000, ePhone],
|
|
[14225000, Phone],
|
|
[14229000, SSTV],
|
|
[14231000, Phone],
|
|
[14281000, AM],
|
|
[14291000, Phone],
|
|
[14350000, None],
|
|
# 17 meters
|
|
[18068000, CW],
|
|
[18100000, RTTY],
|
|
[18105000, Packet],
|
|
[18110000, Phone],
|
|
[18168000, None],
|
|
# 15 meters
|
|
[21000000, eCW],
|
|
[21025000, CW],
|
|
[21070000, RTTY],
|
|
[21110000, CW],
|
|
[21200000, ePhone],
|
|
[21275000, Phone],
|
|
[21339000, SSTV],
|
|
[21341000, Phone],
|
|
[21450000, None],
|
|
# 12 meters
|
|
[24890000, CW],
|
|
[24920000, RTTY],
|
|
[24925000, Packet],
|
|
[24930000, Phone],
|
|
[24990000, None],
|
|
# 10 meters
|
|
[28000000, CW],
|
|
[28070000, RTTY],
|
|
[28150000, CW],
|
|
[28200000, Beacons],
|
|
[28300000, Phone],
|
|
[28679000, SSTV],
|
|
[28681000, Phone],
|
|
[29000000, AM],
|
|
[29200000, Phone],
|
|
[29300000, Satellite],
|
|
[29520000, Repeater],
|
|
[29590000, Simplex],
|
|
[29610000, Repeater],
|
|
[29700000, None],
|
|
# 6 meters
|
|
[50000000, Beacons],
|
|
[50100000, Phone],
|
|
[54000000, None],
|
|
# 4 meters
|
|
[70000000, Phone],
|
|
[70500000, None],
|
|
# 2 meters
|
|
[144000000, CW],
|
|
[144200000, Phone],
|
|
[144275000, Beacons],
|
|
[144300000, Satellite],
|
|
[144380000, Special],
|
|
[144400000, Satellite],
|
|
[144500000, RepInput],
|
|
[144900000, Other],
|
|
[145100000, Repeater],
|
|
[145500000, Other],
|
|
[145800000, Satellite],
|
|
[146010000, RepInput],
|
|
[146400000, Simplex],
|
|
[146510000, Special], # Simplex calling frequency
|
|
[146530000, Simplex],
|
|
[146610000, Repeater],
|
|
[147420000, Simplex],
|
|
[147600000, RepInput],
|
|
[148000000, None],
|
|
# 1.25 meters
|
|
[222000000, Phone],
|
|
[222250000, RepInput],
|
|
[223400000, Simplex],
|
|
[223520000, Data],
|
|
[223640000, Repeater],
|
|
[225000000, None],
|
|
#70 centimeters
|
|
[420000000, SSTV],
|
|
[432000000, Satellite],
|
|
[432070000, Phone],
|
|
[432300000, Beacons],
|
|
[432400000, Phone],
|
|
[433000000, Repeater],
|
|
[435000000, Satellite],
|
|
[438000000, Repeater],
|
|
[445900000, Simplex],
|
|
[445990000, Special], # Simplex calling frequency
|
|
[446010000, Simplex],
|
|
[446100000, Repeater],
|
|
[450000000, None],
|
|
# 33 centimeters
|
|
[902000000, Other],
|
|
[928000000, None],
|
|
# 23 centimeters
|
|
[1240000000, Other],
|
|
[1300000000, None],
|
|
# 13 centimeters
|
|
[2300000000, Other],
|
|
[2450000000, None],
|
|
# 9 centimeters
|
|
[3300000000, Other],
|
|
[3500000000, None],
|
|
# 5 centimeters
|
|
[5650000000, Other],
|
|
[5925000000, None],
|
|
# 3 centimeters
|
|
[10000000000, Other],
|
|
[10500000000, None],
|
|
]
|
|
|
|
## BandEdge Band Edge, dict
|
|
# For each band, this dictionary gives the lower and upper band edges. Frequencies
|
|
# outside these limits will not be remembered as the last frequency in the band.
|
|
BandEdge = {
|
|
'137k':( 136000, 138000), '500k':( 400000, 600000),
|
|
'160':( 1800000, 2000000), '80' :( 3500000, 4000000),
|
|
'60' :( 5300000, 5430000), '40' :( 7000000, 7300000),
|
|
'30' :(10100000, 10150000), '20' :(14000000, 14350000),
|
|
'17' :(18068000, 18168000), '15' :(21000000, 21450000),
|
|
'12' :(24890000, 24990000), '10' :(28000000, 29700000),
|
|
'6' :( 50000000, 54000000),
|
|
'4' :( 70000000, 70500000),
|
|
'2' :( 144000000, 148000000),
|
|
'1.25' :( 222000000, 225000000),
|
|
'70cm' :( 420000000, 450000000),
|
|
'33cm' :( 902000000, 928000000),
|
|
'23cm' :(1240000000, 1300000000),
|
|
'13cm' :(2300000000, 2450000000),
|
|
'9cm' :(3300000000, 3500000000),
|
|
'5cm' :(5650000000, 5925000000),
|
|
'3cm' :(10000000000,10500000000),
|
|
}
|
|
|
|
# For the Time band, this is the center frequency, tuning frequency and mode:
|
|
bandTime = [
|
|
( 2500000-10000, 10000, 'AM'),
|
|
( 3330000-10000, 10000, 'AM'),
|
|
( 5000000-10000, 10000, 'AM'),
|
|
( 7335000-10000, 10000, 'AM'),
|
|
(10000000-10000, 10000, 'AM'),
|
|
(14670000-10000, 10000, 'AM'),
|
|
(15000000-10000, 10000, 'AM'),
|
|
(20000000-10000, 10000, 'AM'),
|
|
]
|
|
|
|
## bandLabels Band Buttons, list
|
|
# This is the list of band buttons that Quisk displays, and it should have
|
|
# a length of 14 or less. Empty buttons can have a null string "" label.
|
|
# Note that the 60 meter band and the Time band have buttons that support
|
|
# multiple presses.
|
|
bandLabels = [
|
|
'Audio', '160', '80', ('60',) * 5, '40', '30', '20', '17',
|
|
'15', '12', '10', ('Time',) * len(bandTime)]
|
|
|
|
# This is a dictionary of shortcut keys for each band. If you do not want a shortcut, use ''. The shortcut
|
|
# character will be underlined in the label if present.
|
|
bandShortcuts = {'Audio':'', '160':'1', '80':'8', '60':'6', '40':'4', '30':'3', '20':'2', '17':'7',
|
|
'15':'5', '12':'1', '10':'0', 'Time':'e', '6':'6', '4':'4', '2':'2', '1.25':'5', '70cm':'7',
|
|
'33cm':'3', '23cm':'', '13cm':'', '9cm':'', '5cm':'', '3cm':''}
|
|
|
|
## bandTransverterOffset Transverter Offset, dict
|
|
# If you use a transverter, you need to tune your hardware to a frequency lower than
|
|
# the frequency displayed by Quisk. For example, if you have a 2 meter transverter,
|
|
# you may need to tune your hardware from 28 to 30 MHz to receive 144 to 146 MHz.
|
|
# Enter the transverter offset in Hertz in this dictionary. For this to work, your
|
|
# hardware must support it. Currently, the HiQSDR, SDR-IQ and SoftRock are supported.
|
|
bandTransverterOffset = {
|
|
# '2': 144000000 - 28000000
|
|
}
|
|
|
|
|
|
|
|
|
|
################ Obsolete
|
|
filter_display = 1 # Display the filter bandwidth on the graph screen; 0 or 1; thanks to WB4JFI
|
|
# For each band, this dictionary gives the initial center frequency, tuning
|
|
# frequency as an offset from the center frequency, and the mode. This is
|
|
# no longer too useful because the persistent_state feature saves and then
|
|
# overwrites these values anyway.
|
|
bandState = {'Audio':(0, 0, 'LSB'),
|
|
'160':( 1890000, -10000, 'LSB'), '80' :( 3660000, -10000, 'LSB'),
|
|
'60' :( 5370000, 1500, 'USB'), '40' :( 7180000, -5000, 'LSB'), '30':(10120000, -10000, 'CWL'),
|
|
'Time':( 5000000, 0, 'AM')}
|
|
for band in BandEdge:
|
|
f1, f2 = BandEdge[band]
|
|
if f1 > 13500000:
|
|
f = (f1 + f2) // 2
|
|
f = (f + 5000) // 10000
|
|
f *= 10000
|
|
bandState[band] = (f, 10000, 'USB')
|
|
# Select the method to test the state of the key; see is_key_down.c
|
|
key_method = "" # No keying, or internal method
|
|
# key_method = "/dev/parport0" # Use the named parallel port
|
|
# key_method = "/dev/ttyS0" # Use the named serial port
|
|
# key_method = "192.168.1.44" # Use UDP from this address
|
|
#
|
|
# Quisk can save its current state in a file on exit, and restore it when you restart.
|
|
# State includes band, frequency and mode, but not every item of state (not screen).
|
|
# The file is .quisk_init.pkl in the same directory as your config file. If this file
|
|
# becomes corrupted, just delete it and it will be reconstructed.
|
|
#persistent_state = False
|
|
persistent_state = True
|
|
# Select the default mode when Quisk starts (overruled by persistent_state):
|
|
# default_mode = 'FM'
|
|
default_mode = 'USB'
|
|
# If you use a soundcard with Ethernet control of the VFO, set these parameters:
|
|
rx_ip = "" # Receiver IP address for VFO control
|
|
# This determines what happens when you tune by dragging the mouse. The correct
|
|
# choice depends on how your hardware performs tuning. You may want to use a
|
|
# custom hardware file with a custom ChangeFrequency() method too.
|
|
mouse_tune_method = 0 # The Quisk tune frequency changes and the VFO frequency is unchanged.
|
|
#mouse_tune_method = 1 # The Quisk tune frequency is unchanged and the VFO changes.
|
|
# configurable mouse wheel thanks to DG7MGY
|
|
mouse_wheelmod = 50 # Round frequency when using mouse wheel (50 Hz)
|