WSJT-X/Transceiver.hpp
Bill Somerville 0504d2af92 Rig frequency calibration
The   settings   are  a   linear   calibration   correction  for   the
rig. Calibration constants are supplied as an intercept error in Hertz
and a slope error in parts per million.

The correction is  applied only to the final frequencies  going to and
from  the radio.   This means  that  any transverter  offsets are  not
corrected. This is  appropriate as each transverter will  have its own
error factors.  Transvertor and  other individual band specific errors
can only be corrected by adjusting the offset for the band.

Thanks  to Mike  W9MDB for  an  initial implementation  of Joe  K1JT's
suggestion. See also the WSPR documentation for details of calculating
the required calibration constants.

git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@5396 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2015-05-19 17:52:47 +00:00

171 lines
5.2 KiB
C++

#ifndef TRANSCEIVER_HPP__
#define TRANSCEIVER_HPP__
#include <QObject>
#include "qt_helpers.hpp"
#include "Radio.hpp"
class QString;
//
// Abstract Transceiver Interface
//
// This is the minimal generic interface to a rig as required by
// wsjtx.
//
// Responsibilities
//
// Provides Qt slots to set the frequency, mode and PTT of some
// transceiver. They are Qt slots so that they may be invoked across
// a thread boundary.
//
// Provides a synchronisation Qt slot which should be implemented in
// sub-classes in such a way that normal operation of the rig is not
// disturbed. This is intended to be use to poll rig state
// periodically and changing VFO to read the other VFO frequency or
// mode for example should not be done since the operator may be
// tuning the VFO at the time and would be surprised by an unprompted
// VFO change.
//
// Provides a control interface using Qt slots to start and stop the
// rig control and PTT connections.
//
// These are Qt slots rather than the constructor and destructor
// because it is expected that the concrete Transceiver
// implementations will run in a separate thread from where they are
// constructed.
//
// Qt signals are defined to notify clients of asynchronous rig state
// changes and failures. These can and are expected to cross thread
// boundaries.
//
// A signal finished() is defined that concrete Transceiver
// implementations must emit when they are ripe for destruction. This
// is intended to be used by clients that move the Transceiver
// instance to a thread and need to use QObject::deleteLater() to
// safely dispose of the Transceiver instance. Implementations should
// expect Qt slot calls after emitting finished, it is up to the
// implementation whether these slot invocations are ignored.
//
class Transceiver
: public QObject
{
Q_OBJECT;
Q_ENUMS (MODE);
public:
using Frequency = Radio::Frequency;
protected:
Transceiver ()
{
}
public:
virtual ~Transceiver ()
{
}
enum MODE {UNK, CW, CW_R, USB, LSB, FSK, FSK_R, DIG_U, DIG_L, AM, FM, DIG_FM};
//
// Aggregation of all of the rig and PTT state accessible via this
// interface.
//
class TransceiverState
{
public:
TransceiverState ()
: online_ {false}
, frequency_ {0, 0}
, mode_ {UNK}
, split_ {unknown}
, ptt_ {false}
{
}
bool online () const {return online_;}
Frequency frequency () const {return frequency_[0];}
Frequency tx_frequency () const {return frequency_[1];}
bool split () const {return on == split_;}
MODE mode () const {return mode_;}
bool ptt () const {return ptt_;}
void online (bool state) {online_ = state;}
void frequency (Frequency f) {frequency_[0] = f;}
void tx_frequency (Frequency f) {frequency_[1] = f;}
void split (bool state) {split_ = state ? on : off;}
void mode (MODE m) {mode_ = m;}
void ptt (bool state) {ptt_ = state;}
private:
bool online_;
Frequency frequency_[2]; // [0] -> Rx; [1] -> Other
MODE mode_;
enum {unknown, off, on} split_;
bool ptt_;
// Don't forget to update the debug print and != operator if you
// add more members here
friend QDebug operator << (QDebug, TransceiverState const&);
friend bool operator != (TransceiverState const&, TransceiverState const&);
};
//
// The following slots and signals are expected to all run in the
// same thread which is not necessarily the main GUI thread. It is
// up to the client of the Transceiver class to organise the
// allocation to a thread and the lifetime of the object instances.
//
// Connect and disconnect.
Q_SLOT virtual void start () noexcept = 0;
Q_SLOT virtual void stop () noexcept = 0;
// Set frequency in Hertz.
Q_SLOT virtual void frequency (Frequency, MODE = UNK) noexcept = 0;
// Setting a non-zero TX frequency means split operation, the value
// zero means simplex operation.
//
// Rationalise_mode means ensure TX uses same mode as RX.
Q_SLOT virtual void tx_frequency (Frequency tx = 0, bool rationalise_mode = true) noexcept = 0;
// Set mode.
// Rationalise means ensure TX uses same mode as RX.
Q_SLOT virtual void mode (MODE, bool rationalise = true) noexcept = 0;
// Set/unset PTT.
Q_SLOT virtual void ptt (bool = true) noexcept = 0;
// Attempt to re-synchronise or query state.
// Force_signal guarantees a update or failure signal.
Q_SLOT virtual void sync (bool force_signal = false) noexcept = 0;
// asynchronous status updates
Q_SIGNAL void update (Transceiver::TransceiverState) const;
Q_SIGNAL void failure (QString reason) const;
// Ready to be destroyed.
Q_SIGNAL void finished () const;
};
Q_DECLARE_METATYPE (Transceiver::TransceiverState);
Q_DECLARE_METATYPE (Transceiver::MODE);
#if !defined (QT_NO_DEBUG_STREAM)
ENUM_QDEBUG_OPS_DECL (Transceiver, MODE);
QDebug operator << (QDebug, Transceiver::TransceiverState const&);
#endif
ENUM_QDATASTREAM_OPS_DECL (Transceiver, MODE);
ENUM_CONVERSION_OPS_DECL (Transceiver, MODE);
bool operator != (Transceiver::TransceiverState const&, Transceiver::TransceiverState const&);
bool operator == (Transceiver::TransceiverState const&, Transceiver::TransceiverState const&);
#endif