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sdrangel/plugins/channelrx/radioastronomy/radioastronomysettings.h

236 lines
8.1 KiB
C++

///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2017 Edouard Griffiths, F4EXB. //
// Copyright (C) 2021 Jon Beniston, M7RCE //
// //
// This program is free software; you can redistribute it and/or modify //
// it under the terms of the GNU General Public License as published by //
// the Free Software Foundation as version 3 of the License, or //
// (at your option) any later version. //
// //
// This program is distributed in the hope that it will be useful, //
// but WITHOUT ANY WARRANTY; without even the implied warranty of //
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the //
// GNU General Public License V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see <http://www.gnu.org/licenses/>. //
///////////////////////////////////////////////////////////////////////////////////
#ifndef INCLUDE_RADIOASTRONOMYSETTINGS_H
#define INCLUDE_RADIOASTRONOMYSETTINGS_H
#include <QByteArray>
#include <QString>
#include <QDateTime>
#include "dsp/dsptypes.h"
class Serializable;
// Number of columns in the tables
#define RADIOASTRONOMY_POWERTABLE_COLUMNS 32
// Number of sensors
#define RADIOASTRONOMY_SENSORS 2
struct RadioAstronomySettings
{
int m_inputFrequencyOffset;
int m_sampleRate;
int m_rfBandwidth;
int m_integration; //!< Number of samples to integrate
int m_fftSize;
enum FFTWindow {
REC,
HAN
} m_fftWindow; //!< FFT windowing function
QString m_filterFreqs; //!< List of channels (bin indices) to filter in FFT to remove RFI
QString m_starTracker; //!< Name of Star Tracker plugin to link with
QString m_rotator; //!< Name of antenna rotator
float m_tempRX; //!< Receiver noise temperature in K (Front end NF)
float m_tempCMB; //!< Cosmic microwave background temperature in K
float m_tempGal; //!< Galactic background temperature in K
float m_tempSP; //!< Spillover temperature in K
float m_tempAtm; //!< Atmospheric temperature in K
float m_tempAir; //!< Surface air temperature in C
float m_zenithOpacity; //!< Opacity of atmosphere at zenith
float m_elevation; //!< Elevation in degrees, if not using value from Star Tracker
bool m_tempGalLink;
bool m_tempAtmLink;
bool m_tempAirLink;
bool m_elevationLink;
float m_gainVariation; //!< delta G/G
enum SourceType {
UNKNOWN,
COMPACT,
EXTENDED,
SUN,
CAS_A
} m_sourceType; //!< Whether the source it smaller than the beam
float m_omegaS; //!< Source angle
enum AngleUnits {
DEGREES,
STERRADIANS
} m_omegaSUnits;
enum AngleUnits m_omegaAUnits;
bool m_spectrumPeaks;
bool m_spectrumMarkers;
bool m_spectrumTemp;
bool m_spectrumReverseXAxis;
bool m_spectrumRefLine;
bool m_spectrumLAB;
bool m_spectrumDistance;
bool m_spectrumLegend;
float m_spectrumReference; //!< In dB
float m_spectrumRange; //!< In dB
float m_spectrumSpan; //!< In Mhz
float m_spectrumCenterFreqOffset; //!< Offset - rather than absolute - In Mhz
bool m_spectrumAutoscale;
enum SpectrumYScale {
SY_DBFS,
SY_SNR,
SY_DBM,
SY_TSYS,
SY_TSOURCE
} m_spectrumYScale;
enum SpectrumBaseline {
SBL_TSYS0,
SBL_TMIN,
SBL_CAL_COLD
} m_spectrumBaseline;
bool m_recalibrate;
float m_tCalHot; //!< Hot calibration antenna noise temperature in K (Sky + Spillover?)
float m_tCalCold; //!< Cold calibration antenna noise temperature in K
enum Line {
HI,
OH,
DI,
CUSTOM_LINE
} m_line; //!< Spectral line to plot and use as Doppler reference
float m_lineCustomFrequency; //!< Spectral line frequency when m_line==CUSTOM
enum RefFrame {
TOPOCENTRIC,
BCRS,
LSR
} m_refFrame; //!< Reference frame for velocities
float m_sunDistanceToGC; //!< Sun distance to Galactic Center In kpc
float m_sunOrbitalVelocity; //!< In km/s around GC
bool m_powerPeaks;
bool m_powerMarkers;
bool m_powerAvg;
bool m_powerLegend;
bool m_powerShowTsys0; //!< Plot total noise temperature
bool m_powerShowAirTemp;
bool m_powerShowGaussian;
bool m_powerShowFiltered;
bool m_powerShowMeasurement;
float m_powerReference; //!< In dB
float m_powerRange; //!< In dB
bool m_powerAutoscale;
enum PowerYData {
PY_POWER,
PY_TSYS,
PY_TSOURCE,
PY_FLUX,
PY_2D_MAP
} m_powerYData;
enum PowerYUnits {
PY_DBFS,
PY_DBM,
PY_WATTS,
PY_KELVIN,
PY_SFU,
PY_JANSKY
} m_powerYUnits;
enum PowerFilter {
FILT_MEDIAN,
FILT_MOVING_AVERAGE,
// TODO: FILT_LPF
} m_powerFilter;
int m_powerFilterN;
enum SweepType {
SWP_AZEL,
SWP_LB,
SWP_OFFSET
};
bool m_power2DLinkSweep; //<! Update setting below to match sweep parameters
SweepType m_power2DSweepType;
int m_power2DWidth;
int m_power2DHeight;
float m_power2DXMin;
float m_power2DXMax;
float m_power2DYMin;
float m_power2DYMax;
bool m_powerColourAutoscale;
float m_powerColourScaleMin;
float m_powerColourScaleMax;
QString m_powerColourPalette;
enum RunMode {
SINGLE,
CONTINUOUS,
SWEEP
} m_runMode;
bool m_sweepStartAtTime;
QDateTime m_sweepStartDateTime;
SweepType m_sweepType;
float m_sweep1Start;
float m_sweep1Stop;
float m_sweep1Step;
float m_sweep1Delay; //!< Delay after rotation before a measurement
float m_sweep2Start;
float m_sweep2Stop;
float m_sweep2Step;
float m_sweep2Delay; //!< Delay after a measurement before starting the next
QString m_sensorName[RADIOASTRONOMY_SENSORS];
QString m_sensorDevice[RADIOASTRONOMY_SENSORS];
QString m_sensorInit[RADIOASTRONOMY_SENSORS];
QString m_sensorMeasure[RADIOASTRONOMY_SENSORS];
bool m_sensorEnabled[RADIOASTRONOMY_SENSORS];
bool m_sensorVisible[RADIOASTRONOMY_SENSORS];
float m_sensorMeasurePeriod;
bool m_gpioEnabled;
int m_gpioPin;
int m_gpioSense;
QString m_startCalCommand;
QString m_stopCalCommand;
float m_calCommandDelay; //!< Delay in seconds after command before starting cal
quint32 m_rgbColor;
QString m_title;
Serializable *m_channelMarker;
Serializable *m_rollupState;
int m_streamIndex; //!< MIMO channel. Not relevant when connected to SI (single Rx).
bool m_useReverseAPI;
QString m_reverseAPIAddress;
uint16_t m_reverseAPIPort;
uint16_t m_reverseAPIDeviceIndex;
uint16_t m_reverseAPIChannelIndex;
int m_workspaceIndex;
QByteArray m_geometryBytes;
bool m_hidden;
int m_powerTableColumnIndexes[RADIOASTRONOMY_POWERTABLE_COLUMNS];//!< How the columns are ordered in the table
int m_powerTableColumnSizes[RADIOASTRONOMY_POWERTABLE_COLUMNS]; //!< Size of the columns in the table
RadioAstronomySettings();
void resetToDefaults();
void setChannelMarker(Serializable *channelMarker) { m_channelMarker = channelMarker; }
void setRollupState(Serializable *rollupState) { m_rollupState = rollupState; }
QByteArray serialize() const;
bool deserialize(const QByteArray& data);
};
#endif /* INCLUDE_RADIOASTRONOMYSETTINGS_H */