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sdrangel/plugins/channelrx/demodapt/aptdemodimageworker.cpp
2024-07-10 23:06:38 +02:00

1031 lines
36 KiB
C++

///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2015-2018 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/>. //
///////////////////////////////////////////////////////////////////////////////////
#include <algorithm>
#include <QTime>
#include <QBuffer>
#include <QDebug>
#include "maincore.h"
#include "util/units.h"
#include "aptdemod.h"
#include "aptdemodimageworker.h"
#include "SWGMapItem.h"
MESSAGE_CLASS_DEFINITION(APTDemodImageWorker::MsgConfigureAPTDemodImageWorker, Message)
MESSAGE_CLASS_DEFINITION(APTDemodImageWorker::MsgSaveImageToDisk, Message)
MESSAGE_CLASS_DEFINITION(APTDemodImageWorker::MsgSetSatelliteName, Message)
APTDemodImageWorker::APTDemodImageWorker(APTDemod *aptDemod) :
m_messageQueueToGUI(nullptr),
m_aptDemod(aptDemod),
m_sgp4(nullptr),
m_running(false)
{
for (int y = 0; y < APT_MAX_HEIGHT; y++)
{
m_image.prow[y] = new float[APT_PROW_WIDTH];
m_tempImage.prow[y] = new float[APT_PROW_WIDTH];
}
resetDecoder();
}
APTDemodImageWorker::~APTDemodImageWorker()
{
m_inputMessageQueue.clear();
for (int y = 0; y < APT_MAX_HEIGHT; y++)
{
delete[] m_image.prow[y];
delete[] m_tempImage.prow[y];
}
delete m_sgp4;
}
void APTDemodImageWorker::reset()
{
QMutexLocker mutexLocker(&m_mutex);
m_inputMessageQueue.clear();
}
void APTDemodImageWorker::startWork()
{
QMutexLocker mutexLocker(&m_mutex);
connect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleInputMessages()));
m_running = true;
}
void APTDemodImageWorker::stopWork()
{
QMutexLocker mutexLocker(&m_mutex);
disconnect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleInputMessages()));
m_running = false;
}
void APTDemodImageWorker::handleInputMessages()
{
Message* message;
while ((message = m_inputMessageQueue.pop()) != nullptr)
{
if (handleMessage(*message)) {
delete message;
}
}
}
bool APTDemodImageWorker::handleMessage(const Message& cmd)
{
if (MsgConfigureAPTDemodImageWorker::match(cmd))
{
QMutexLocker mutexLocker(&m_mutex);
MsgConfigureAPTDemodImageWorker& cfg = (MsgConfigureAPTDemodImageWorker&) cmd;
qDebug("APTDemodImageWorker::handleMessage: MsgConfigureAPTDemodImageWorker");
applySettings(cfg.getSettings(), cfg.getForce());
return true;
}
else if (MsgSaveImageToDisk::match(cmd))
{
saveImageToDisk();
return true;
}
else if (MsgSetSatelliteName::match(cmd))
{
MsgSetSatelliteName& msg = (MsgSetSatelliteName&) cmd;
m_satelliteName = msg.getSatelliteName();
return true;
}
else if (APTDemod::MsgPixels::match(cmd))
{
QMutexLocker mutexLocker(&m_mutex);
const APTDemod::MsgPixels& pixelsMsg = (APTDemod::MsgPixels&) cmd;
const float *pixels = pixelsMsg.getPixels();
processPixels(pixels);
delete[] pixels;
return true;
}
else if (APTDemod::MsgResetDecoder::match(cmd))
{
resetDecoder();
return true;
}
else
{
return false;
}
}
void APTDemodImageWorker::applySettings(const APTDemodSettings& settings, bool force)
{
(void) force;
bool callRecalcCoords = false;
bool callProcessImage = false;
if ((settings.m_cropNoise != m_settings.m_cropNoise) ||
(settings.m_denoise != m_settings.m_denoise) ||
(settings.m_linearEqualise != m_settings.m_linearEqualise) ||
(settings.m_histogramEqualise != m_settings.m_histogramEqualise) ||
(settings.m_precipitationOverlay != m_settings.m_precipitationOverlay) ||
(settings.m_flip != m_settings.m_flip) ||
(settings.m_channels != m_settings.m_channels) ||
(settings.m_transparencyThreshold != m_settings.m_transparencyThreshold) ||
(settings.m_opacityThreshold != m_settings.m_opacityThreshold) ||
(settings.m_palettes != m_settings.m_palettes) ||
(settings.m_palette != m_settings.m_palette) ||
(settings.m_horizontalPixelsPerDegree != m_settings.m_horizontalPixelsPerDegree) ||
(settings.m_verticalPixelsPerDegree != m_settings.m_verticalPixelsPerDegree))
{
// Call after settings have been applied
callProcessImage = true;
}
if ((settings.m_satTimeOffset != m_settings.m_satTimeOffset) ||
(settings.m_satYaw != m_settings.m_satYaw))
{
callRecalcCoords = true;
callProcessImage = true;
}
if (!settings.m_decodeEnabled && m_settings.m_decodeEnabled)
{
// Decode complete - make sure we do a full image update
// so we aren't left we unprocessed lines
callProcessImage = true;
}
if (settings.m_palettes != m_settings.m_palettes)
{
// Load colour palettes
m_palettes.clear();
for (auto palette : settings.m_palettes)
{
QImage img;
img.load(palette);
if ((img.width() != 256) || (img.height() != 256)) {
qWarning() << "APT colour palette " << palette << " is not 256x256 pixels - " << img.width() << "x" << img.height();
}
m_palettes.append(img);
}
}
m_settings = settings;
if (callRecalcCoords) {
recalcCoords();
}
if (callProcessImage) {
sendImageToGUI();
}
}
void APTDemodImageWorker::resetDecoder()
{
m_image.nrow = 0;
m_tempImage.nrow = 0;
m_greyImage = QImage(APT_IMG_WIDTH, APT_MAX_HEIGHT, QImage::Format_Grayscale8);
m_greyImage.fill(0);
m_colourImage = QImage(APT_IMG_WIDTH, APT_MAX_HEIGHT, QImage::Format_RGB888);
m_colourImage.fill(0);
m_satelliteName = "";
m_satCoords.clear();
m_pixelCoords.clear();
delete m_sgp4;
m_sgp4 = nullptr;
}
// Convert Qt QDataTime to QGP4 DateTime
static DateTime qDateTimeToDateTime(QDateTime qdt)
{
QDateTime utc = qdt.toUTC();
QDate date = utc.date();
QTime time = utc.time();
DateTime dt;
dt.Initialise(date.year(), date.month(), date.day(), time.hour(), time.minute(), time.second(), time.msec() * 1000);
return dt;
}
// Get heading in range [0,360)
static double normaliseHeading(double heading)
{
return fmod(heading + 360.0, 360.0);
}
// Get longitude in range -180,180
static double normaliseLongitude(double lon)
{
return fmod(lon + 540.0, 360.0) - 180.0;
}
// Calculate heading (azimuth) in degrees
double APTDemodImageWorker::calcHeading(CoordGeodetic from, CoordGeodetic to) const
{
// From https://en.wikipedia.org/wiki/Azimuth Section In Geodesy
double flattening = 1.0 / 298.257223563; // For WGS84 ellipsoid
double eSq = flattening * (2.0 - flattening);
double oneMinusESq = (1.0 - flattening) * (1.0 - flattening);
double tl1 = tan(from.latitude);
double tl2 = tan(to.latitude);
double n1 = 1.0 + oneMinusESq * tl2 * tl2;
double d1 = 1.0 + oneMinusESq * tl1 * tl1;
double l = to.longitude - from.longitude;
double alpha;
if (from.latitude == 0.0)
{
alpha = atan2(sin(l), (oneMinusESq * tan(to.latitude)));
}
else
{
double lambda = oneMinusESq * tan(to.latitude) / tan(from.latitude) + eSq * sqrt(n1/d1);
alpha = atan2(sin(l), ((lambda - cos(l)) * sin(from.latitude)));
}
double deg = Units::radiansToDegrees(alpha);
if (!m_settings.m_northToSouth) {
deg += 180.0;
}
deg = normaliseHeading(deg);
return deg;
}
// CoordGeodetic are in radians. Distance in metres. Bearing in radians.
// https://www.movable-type.co.uk/scripts/latlong.html
// This approximates Earth as spherical. If we need more accurate algorithm, see:
// https://www.movable-type.co.uk/scripts/latlong-vincenty.html
static void calcRadialEndPoint(CoordGeodetic start, double distance, double bearing, CoordGeodetic &end)
{
double earthRadius = 6378137.0; // At equator
double delta = distance/earthRadius;
end.latitude = std::asin(sin(start.latitude)*cos(delta) + cos(start.latitude)*sin(delta)*cos(bearing));
end.longitude = start.longitude + std::atan2(sin(bearing)*sin(delta)*cos(start.latitude), cos(delta) - sin(start.latitude)*sin(end.latitude));
end.longitude = normaliseLongitude(end.longitude);
}
void APTDemodImageWorker::calcPixelCoords(CoordGeodetic centreCoord, double heading)
{
// Calculate coordinates of each pixel in a row (swath)
// Assume satellite is at centre pixel, and project +-90 degrees from satellite heading
// https://www.ncei.noaa.gov/pub/data/satellite/publications/podguides/N-15%20thru%20N-19/pdf/APPENDIX%20J%20Instrument%20Scan%20Properties.pdf
// Swath for AVHRR/3 of 2926.6km at 833km altitude over spherical Earth
// Some docs say resolution is 4.0km, but it varies as per fig 4.2.3-1 in:
// https://www.ncei.noaa.gov/pub/data/satellite/publications/podguides/N-15%20thru%20N-19/pdf/2.1%20Section%204.0%20Real%20Time%20Data%20Systems%20for%20Local%20Users%20.pdf
// TODO: Could try to adjust for altitude
QVector<CoordGeodetic> pixelCoords(APT_CH_WIDTH);
pixelCoords[APT_CH_WIDTH/2] = centreCoord;
double heading1 = Units::degreesToRadians(heading + m_settings.m_satYaw + 90.0);
double heading2 = Units::degreesToRadians(heading + m_settings.m_satYaw - 90.0);
for (int i = 1; i <= APT_CH_WIDTH/2; i++)
{
double distance = i * 2926600.0/APT_CH_WIDTH;
calcRadialEndPoint(centreCoord, distance, heading1, pixelCoords[APT_CH_WIDTH/2-i]);
calcRadialEndPoint(centreCoord, distance, heading2, pixelCoords[APT_CH_WIDTH/2+i]);
}
if (m_settings.m_northToSouth) {
m_pixelCoords.append(pixelCoords);
} else {
m_pixelCoords.prepend(pixelCoords);
}
}
// Recalculate all pixel coordinates as satTimeOffset or satYaw has changed
void APTDemodImageWorker::recalcCoords()
{
if (m_sgp4)
{
m_satCoords.clear();
m_pixelCoords.clear();
for (int row = 0; row < m_image.nrow; row++)
{
QDateTime qdt = m_settings.m_aosDateTime.addMSecs(m_settings.m_satTimeOffset * 1000.0f + row * 500);
calcCoords(qdt, row);
}
}
}
// Calculate pixel coordinates for a single row at the given date and time
void APTDemodImageWorker::calcCoords(QDateTime qdt, int row)
{
try
{
DateTime dt = qDateTimeToDateTime(qdt);
// Calculate satellite position
Eci eci = m_sgp4->FindPosition(dt);
// Convert satellite position to geodetic coordinates (lat and long)
CoordGeodetic geo = eci.ToGeodetic();
m_satCoords.append(geo);
// Calculate satellite heading (Could convert eci.Velocity() instead)
double heading;
if (m_satCoords.size() == 2)
{
heading = calcHeading(m_satCoords[0], m_satCoords[1]);
calcPixelCoords(m_satCoords[0], heading);
calcPixelCoords(m_satCoords[1], heading);
}
else if (m_satCoords.size() > 2)
{
heading = calcHeading(m_satCoords[row-1], m_satCoords[row]);
calcPixelCoords(geo, heading);
}
}
catch (SatelliteException& se)
{
qDebug() << "APTDemodImageWorker::calcCoord: " << se.what();
}
catch (DecayedException& de)
{
qDebug() << "APTDemodImageWorker::calcCoord: " << de.what();
}
catch (TleException& tlee)
{
qDebug() << "APTDemodImageWorker::calcCoord: " << tlee.what();
}
}
// Calculate satellite's geodetic coordinates and heading
void APTDemodImageWorker::calcCoord(int row)
{
if (row == 0)
{
QStringList elements = m_settings.m_tle.trimmed().split("\n");
if (elements.size() == 3)
{
// Initialise SGP4
Tle tle(elements[0].toStdString(), elements[1].toStdString(), elements[2].toStdString());
m_sgp4 = new SGP4(tle);
// Output time so we can check time offset from when AOS is signalled
qDebug() << "APTDemod: Processing row 0 at " << QDateTime::currentDateTime();
calcCoords(m_settings.m_aosDateTime, row);
}
else
{
qDebug() << "APTDemodImageWorker::calcCoord: No TLE for satellite. Is Satellite Tracker running?";
return;
}
}
else if (m_sgp4 == nullptr)
{
return;
}
else
{
// Calculate time at which
// Don't try to use QDateTime::currentDateTime() as processing & scheduling delays mean
// it's not constant and can sometimes even be 0
// Lines should be transmitted at 2 per second, so just use number of rows since AOS
// We add a user-defined delay to account for delays in transferring SDR data and demodulation
QDateTime qdt = m_settings.m_aosDateTime.addMSecs(m_settings.m_satTimeOffset * 1000.0f + row * 500);
calcCoords(qdt, row);
}
}
void APTDemodImageWorker::processPixels(const float *pixels)
{
if (m_image.nrow < APT_MAX_HEIGHT)
{
// Calculate lat and lon of centre of row
calcCoord(m_image.nrow);
std::copy(pixels, pixels + APT_PROW_WIDTH, m_image.prow[m_image.nrow]);
m_image.nrow++;
if (m_image.nrow % m_settings.m_scanlinesPerImageUpdate == 0) { // send full image only every N lines
sendImageToGUI();
} else { // else send unprocessed line just to show stg is moving
sendLineToGUI();
}
}
}
void APTDemodImageWorker::sendImageToGUI()
{
// Send image to GUI
if (m_messageQueueToGUI)
{
QStringList imageTypes;
QImage image = processImage(imageTypes, m_settings.m_channels);
m_messageQueueToGUI->push(APTDemod::MsgImage::create(image, imageTypes, m_satelliteName));
if (m_sgp4) {
sendImageToMap(image);
}
}
}
// Find the value of the pixel closest to the given coordinates
// If we have previously found a pixel, we constrain the search to be nearby, in order to speed up the search
QRgb APTDemodImageWorker::findNearest(const QImage &image, double latitude, double longitude, int xPrevious, int yPrevious, int &xNearest, int &yNearest) const
{
double dmin = 360.0 * 360.0 + 90.0 * 90.0;
xNearest = -1;
yNearest = -1;
QRgb p = qRgba(0, 0, 0, 0); // Transparent
int xMin, xMax;
int yMin, yMax;
int yStartPostCrop;
int yEndPostCrop;
if (m_settings.m_northToSouth)
{
yStartPostCrop = 0;
yEndPostCrop = yStartPostCrop + image.height();
}
else
{
yStartPostCrop = m_image.nrow - m_tempImage.nrow;
yEndPostCrop = yStartPostCrop + image.height();
}
if (xPrevious == -1)
{
yMin = yStartPostCrop;
yMax = yEndPostCrop;
xMin = 0;
xMax = m_pixelCoords[0].size();
}
else
{
int searchRadius = 4;
yMin = yPrevious - searchRadius;
yMax = yPrevious + searchRadius + 1;
xMin = xPrevious - searchRadius;
xMax = xPrevious + searchRadius + 1;
yMin = std::max(yMin, yStartPostCrop);
yMax = std::min(yMax, yEndPostCrop);
xMin = std::max(xMin, 0);
xMax = std::min(xMax, (int)m_pixelCoords[0].size());
}
const int ySize = yEndPostCrop-1;
const int xSize = m_pixelCoords[0].size()-1;
for (int y = yMin; y < yMax; y++)
{
for (int x = xMin; x < xMax; x++)
{
CoordGeodetic coord = m_pixelCoords[y][x];
double dlat = coord.latitude - latitude;
double dlon = coord.longitude - longitude;
double d = dlat * dlat + dlon * dlon;
if (d < dmin)
{
dmin = d;
xNearest = x;
yNearest = y;
// Only use color of pixel if we're inside the source image
if ( ((y != yStartPostCrop) || ((y == yStartPostCrop) && (latitude <= coord.latitude)))
&& ((y != ySize) || ((y == ySize) && (latitude >= coord.latitude)))
&& ((x != 0) || ((x == 0) && (longitude >= coord.longitude)))
&& ((x != xSize) || ((x == xSize) && (longitude <= coord.longitude)))
)
{
p = image.pixel(x, y - yStartPostCrop);
}
else
{
p = qRgba(0, 0, 0, 0); // Transparent
}
}
}
}
return p;
}
// Calculate bounding box for projected image in terms of latitude and longitude
// TODO: Handle crossing of anti-meridian
void APTDemodImageWorker::calcBoundingBox(double &east, double &south, double &west, double &north, const QImage &image)
{
int start;
if (m_settings.m_northToSouth) {
start = 0;
} else {
start = m_image.nrow - m_tempImage.nrow;
}
int stop = start + image.height();
east = -M_PI;
west = M_PI;
north = -M_PI/2.0;
south = M_PI/2.0;
//FILE *f = fopen("coords.txt", "w");
for (int y = start; y < stop; y++)
{
for (int x = 0; x < m_pixelCoords[y].size(); x++)
{
double latitude = m_pixelCoords[y][x].latitude;
double longitude = m_pixelCoords[y][x].longitude;
//fprintf(f, "%f,%f ", Units::radiansToDegrees(m_pixelCoords[y][x].latitude), Units::radiansToDegrees(m_pixelCoords[y][x].longitude));
south = std::min(latitude, south);
north = std::max(latitude, north);
east = std::max(longitude, east);
west = std::min(longitude, west);
}
//fprintf(f, "\n");
}
//fclose(f);
}
// Project satellite image to equidistant cylindrical projection (Plate Carree) for use on 3D Map
// We've previously computed lat and lon for each pixel in satellite image
// so we just work through coords in projected image, trying to find closest pixel in satellite image
// FIXME: How do we handle sat going over the poles?
QImage APTDemodImageWorker::projectImage(const QImage &image)
{
double east, south, west, north;
// Calculate bounding box for image tile
calcBoundingBox(east, south, west, north, image);
m_tileEast = ceil(Units::radiansToDegrees(east));
m_tileWest = floor(Units::radiansToDegrees(west));
m_tileNorth = ceil(Units::radiansToDegrees(north));
m_tileSouth = floor(Units::radiansToDegrees(south));
double widthDeg = m_tileEast - m_tileWest;
double heightDeg = m_tileNorth - m_tileSouth;
int width = widthDeg * m_settings.m_horizontalPixelsPerDegree;
int height = heightDeg * m_settings.m_verticalPixelsPerDegree;
//image.save("source.png");
//FILE *f = fopen("mapping.txt", "w");
QImage projection(width, height, QImage::Format_ARGB32);
int xNearest, yNearest, xPrevious, yPrevious;
xPrevious = -1;
yPrevious = -1;
for (int y = 0; y < height; y++)
{
// Calculate geodetic coords of pixel in projected image
double lat = m_tileNorth - (y / (double)m_settings.m_verticalPixelsPerDegree);
// Reverse search direction in alternate rows, so we are always seaching
// close to previously found pixel
if ((y & 1) == 0)
{
for (int x = 0; x < width; x++)
{
double lon = m_tileWest + (x / (double)m_settings.m_horizontalPixelsPerDegree);
// Find closest pixel in source image
QRgb pixel = findNearest(image, Units::degreesToRadians(lat), Units::degreesToRadians(lon), xPrevious, yPrevious, xNearest, yNearest);
xPrevious = xNearest;
yPrevious = yNearest;
projection.setPixel(x, y, pixel);
//fprintf(f, "%f,%f,%d,%d,%d ", lat, lon, xNearest, yNearest, pixel==0);
}
}
else
{
for (int x = width - 1; x >= 0; x--)
{
double lon = m_tileWest + (x / (double)m_settings.m_horizontalPixelsPerDegree);
// Find closest pixel in source image
QRgb pixel = findNearest(image, Units::degreesToRadians(lat), Units::degreesToRadians(lon), xPrevious, yPrevious, xNearest, yNearest);
xPrevious = xNearest;
yPrevious = yNearest;
projection.setPixel(x, y, pixel);
//fprintf(f, "%f,%f,%d,%d,%d ", lat, lon, xNearest, yNearest, pixel==0);
}
}
//fprintf(f, "\n");
}
//fclose(f);
return projection;
}
// Make an image transparent, so when overlaid on 3D map, we can see the underlying terrain
// Image is full transparent below m_transparencyThreshold and fully opaque above m_opacityThreshold
void APTDemodImageWorker::makeTransparent(QImage &image)
{
for (int y = 0; y < image.height(); y++)
{
for (int x = 0; x < image.width(); x++)
{
QRgb pixel = image.pixel(x, y);
int grey = qGray(pixel);
if (grey < m_settings.m_transparencyThreshold)
{
// Make fully transparent
pixel = qRgba(qRed(pixel), qGreen(pixel), qBlue(pixel), 0);
image.setPixel(x, y, pixel);
}
else if (grey < m_settings.m_opacityThreshold)
{
// Make slightly transparent
float opacity = 1.0f - ((m_settings.m_opacityThreshold - grey) / (float)(m_settings.m_opacityThreshold - m_settings.m_transparencyThreshold));
opacity = opacity * 255.0f;
opacity = std::min(255.0f, opacity);
opacity = std::max(0.0f, opacity);
pixel = qRgba(qRed(pixel), qGreen(pixel), qBlue(pixel), (int)std::round(opacity));
image.setPixel(x, y, pixel);
}
}
}
}
void APTDemodImageWorker::sendImageToMap(QImage image)
{
// Send to Map feature
QList<ObjectPipe*> mapPipes;
MainCore::instance()->getMessagePipes().getMessagePipes(m_aptDemod, "mapitems", mapPipes);
if (mapPipes.size() > 0)
{
// Only display one channel on map
QImage selectedChannel;
if (m_settings.m_channels == APTDemodSettings::BOTH_CHANNELS) {
selectedChannel = extractImage(image, APTDemodSettings::CHANNEL_B);
} else {
selectedChannel = image;
}
// Project image to geodetic coords (lat & lon)
selectedChannel = projectImage(selectedChannel);
//selectedChannel.save("projected.png");
// Use alpha channel to remove land & sea
makeTransparent(selectedChannel);
// Encode image as base64 PNG
QByteArray ba;
QBuffer buffer(&ba);
buffer.open(QIODevice::WriteOnly);
selectedChannel.save(&buffer, "PNG");
QByteArray data = ba.toBase64();
// Create name for the image
QString satName = m_satelliteName;
satName.replace(" ", "_");
QString name = QString("apt_%1_%2").arg(satName).arg(m_settings.m_aosDateTime.toString("yyyyMMdd_hhmmss"));
// Send name to GUI
m_messageQueueToGUI->push(APTDemod::MsgMapImageName::create(name));
for (const auto& pipe : mapPipes)
{
MessageQueue *messageQueue = qobject_cast<MessageQueue*>(pipe->m_element);
SWGSDRangel::SWGMapItem *swgMapItem = new SWGSDRangel::SWGMapItem();
swgMapItem->setName(new QString(name));
swgMapItem->setImage(new QString(data));
swgMapItem->setAltitude(3000.0); // Typical cloud height - So it appears above objects on the ground
swgMapItem->setType(1);
swgMapItem->setImageTileEast(m_tileEast);
swgMapItem->setImageTileWest(m_tileWest);
swgMapItem->setImageTileNorth(m_tileNorth);
swgMapItem->setImageTileSouth(m_tileSouth);
// FIXME: This isn't correct. Possibly need to use different projection
double earthCircumference = 40075016.686;
double latitude = m_tileSouth + (m_tileNorth - m_tileSouth) / 2.0;
double scale = std::cos(Units::degreesToRadians(latitude));
double zoom = std::log2(earthCircumference * scale * selectedChannel.width() / 2926600) - 8;
swgMapItem->setImageZoomLevel(zoom);
MainCore::MsgMapItem *msg = MainCore::MsgMapItem::create(m_aptDemod, swgMapItem);
messageQueue->push(msg);
}
}
}
void APTDemodImageWorker::sendLineToGUI()
{
if (m_messageQueueToGUI)
{
float *pixels = m_image.prow[m_image.nrow-1];
uchar *line;
APTDemod::MsgLine *msg = APTDemod::MsgLine::create(&line);
if (m_settings.m_channels == APTDemodSettings::BOTH_CHANNELS)
{
for (int i = 0; i < APT_IMG_WIDTH; i++) {
line[i] = roundAndClip(pixels[i]);
}
msg->setSize(APT_IMG_WIDTH);
}
else if (m_settings.m_channels == APTDemodSettings::CHANNEL_A)
{
for (int i = 0; i < APT_CH_WIDTH; i++) {
line[i] = roundAndClip(pixels[i + APT_CHA_OFFSET]);
}
msg->setSize(APT_CH_WIDTH);
}
else
{
for (int i = 0; i < APT_CH_WIDTH; i++) {
line[i] = roundAndClip(pixels[i + APT_CHB_OFFSET]);
}
msg->setSize(APT_CH_WIDTH);
}
m_messageQueueToGUI->push(msg);
}
}
QImage APTDemodImageWorker::processImage(QStringList& imageTypes, APTDemodSettings::ChannelSelection channels)
{
copyImage(&m_tempImage, &m_image);
// Calibrate channels according to wavelength (1.7x to stop flickering)
if (m_tempImage.nrow >= 1.7 * APT_CALIBRATION_ROWS)
{
m_tempImage.chA = apt_calibrate(m_tempImage.prow, m_tempImage.nrow, APT_CHA_OFFSET, APT_CH_WIDTH);
m_tempImage.chB = apt_calibrate(m_tempImage.prow, m_tempImage.nrow, APT_CHB_OFFSET, APT_CH_WIDTH);
QStringList channelTypes({
"", // Unknown
"Visible (0.58-0.68 um)",
"Near-IR (0.725-1.0 um)",
"Near-IR (1.58-1.64 um)",
"Thermal-infrared (10.3-11.3 um)",
"Thermal-infrared (11.5-12.5 um)",
"Mid-infrared (3.55-3.93 um)"
});
imageTypes.append(channelTypes[m_tempImage.chA]);
imageTypes.append(channelTypes[m_tempImage.chB]);
}
// Crop noise due to low elevation at top and bottom of image
if (m_settings.m_cropNoise) {
apt_cropNoise(&m_tempImage);
}
// Denoise filter
if (m_settings.m_denoise)
{
apt_denoise(m_tempImage.prow, m_tempImage.nrow, APT_CHA_OFFSET, APT_CH_WIDTH);
apt_denoise(m_tempImage.prow, m_tempImage.nrow, APT_CHB_OFFSET, APT_CH_WIDTH);
}
// Flip image if satellite pass is North to South
if (m_settings.m_flip)
{
apt_flipImage(&m_tempImage, APT_CH_WIDTH, APT_CHA_OFFSET);
apt_flipImage(&m_tempImage, APT_CH_WIDTH, APT_CHB_OFFSET);
}
// Linear equalise to improve contrast
if (m_settings.m_linearEqualise)
{
apt_linearEnhance(m_tempImage.prow, m_tempImage.nrow, APT_CHA_OFFSET, APT_CH_WIDTH);
apt_linearEnhance(m_tempImage.prow, m_tempImage.nrow, APT_CHB_OFFSET, APT_CH_WIDTH);
}
// Histogram equalise to improve contrast
if (m_settings.m_histogramEqualise)
{
apt_histogramEqualise(m_tempImage.prow, m_tempImage.nrow, APT_CHA_OFFSET, APT_CH_WIDTH);
apt_histogramEqualise(m_tempImage.prow, m_tempImage.nrow, APT_CHB_OFFSET, APT_CH_WIDTH);
}
if (m_settings.m_precipitationOverlay)
{
// Overlay precipitation
for (int r = 0; r < m_tempImage.nrow; r++)
{
uchar *l = m_colourImage.scanLine(r);
for (int i = 0; i < APT_IMG_WIDTH; i++)
{
float p = m_tempImage.prow[r][i];
if ((i >= APT_CHB_OFFSET) && (i < APT_CHB_OFFSET + APT_CH_WIDTH) && (p >= 198))
{
apt_rgb_t rgb = apt_applyPalette(apt_PrecipPalette, p - 198);
// Negative float values get converted to positive uchars here
l[i*3] = (uchar)rgb.r;
l[i*3+1] = (uchar)rgb.g;
l[i*3+2] = (uchar)rgb.b;
int a = i - APT_CHB_OFFSET + APT_CHA_OFFSET;
l[a*3] = (uchar)rgb.r;
l[a*3+1] = (uchar)rgb.g;
l[a*3+2] = (uchar)rgb.b;
}
else
{
uchar q = roundAndClip(p);
l[i*3] = q;
l[i*3+1] = q;
l[i*3+2] = q;
}
}
}
return extractImage(m_colourImage, channels);
}
if (channels == APTDemodSettings::VISIBLE)
{
// Visible calibration
int satnum = 15;
if (m_satelliteName == "NOAA 18") {
satnum = 18;
} else if (m_satelliteName == "NOAA 19") {
satnum = 19;
}
apt_calibrate_visible(satnum, &m_tempImage, APT_CHA_OFFSET, APT_CH_WIDTH);
}
if (channels == APTDemodSettings::TEMPERATURE)
{
// Temperature calibration
int satnum = 15;
if (m_satelliteName == "NOAA 18") {
satnum = 18;
} else if (m_satelliteName == "NOAA 19") {
satnum = 19;
}
apt_calibrate_thermal(satnum, &m_tempImage, APT_CHB_OFFSET, APT_CH_WIDTH);
// Apply colour palette
for (int r = 0; r < m_tempImage.nrow; r++)
{
uchar *l = m_colourImage.scanLine(r);
for (int i = 0; i < APT_CH_WIDTH; i++)
{
float p = m_tempImage.prow[r][i+APT_CHB_OFFSET];
uchar q = roundAndClip(p);
l[i*3] = apt_TempPalette[q*3];
l[i*3+1] = apt_TempPalette[q*3+1];
l[i*3+2] = apt_TempPalette[q*3+2];
}
}
return m_colourImage.copy(0, 0, APT_CH_WIDTH, m_tempImage.nrow);
}
else if (channels == APTDemodSettings::PALETTE)
{
if ((m_settings.m_palette >= 0) && (m_settings.m_palette < m_palettes.size()))
{
// Apply colour palette
for (int r = 0; r < m_tempImage.nrow; r++)
{
uchar *l = m_colourImage.scanLine(r);
for (int i = 0; i < APT_CH_WIDTH; i++)
{
float pA = m_tempImage.prow[r][i+APT_CHA_OFFSET];
float pB = m_tempImage.prow[r][i+APT_CHB_OFFSET];
uchar qA = roundAndClip(pA);
uchar qB = roundAndClip(pB);
QRgb rgb = m_palettes[m_settings.m_palette].pixel(qA, qB);
l[i*3] = qRed(rgb);
l[i*3+1] = qGreen(rgb);
l[i*3+2] = qBlue(rgb);
}
}
return m_colourImage.copy(0, 0, APT_CH_WIDTH, m_tempImage.nrow);
}
else
{
qDebug() << "APTDemodImageWorker::processImage - Illegal palette number: " << m_settings.m_palette;
return QImage();
}
}
else
{
// Extract grey-scale image
for (int r = 0; r < m_tempImage.nrow; r++)
{
uchar *l = m_greyImage.scanLine(r);
for (int i = 0; i < APT_IMG_WIDTH; i++)
{
float p = m_tempImage.prow[r][i];
l[i] = roundAndClip(p);
}
}
return extractImage(m_greyImage, channels);
}
}
QImage APTDemodImageWorker::extractImage(QImage image, APTDemodSettings::ChannelSelection channels)
{
if (channels == APTDemodSettings::BOTH_CHANNELS) {
return image.copy(0, 0, APT_IMG_WIDTH, m_tempImage.nrow);
} else if ((channels == APTDemodSettings::CHANNEL_A) || (channels == APTDemodSettings::VISIBLE)) {
return image.copy(APT_CHA_OFFSET, 0, APT_CH_WIDTH, m_tempImage.nrow);
} else {
return image.copy(APT_CHB_OFFSET, 0, APT_CH_WIDTH, m_tempImage.nrow);
}
}
void APTDemodImageWorker::prependPath(QString &filename)
{
if (!m_settings.m_autoSavePath.isEmpty())
{
if (m_settings.m_autoSavePath.endsWith('/')) {
filename = m_settings.m_autoSavePath + filename;
} else {
filename = m_settings.m_autoSavePath + '/' + filename;
}
}
}
void APTDemodImageWorker::saveImageToDisk()
{
QStringList imageTypes;
QImage image = processImage(imageTypes, APTDemodSettings::BOTH_CHANNELS);
if (image.height() >= m_settings.m_autoSaveMinScanLines)
{
QString filename;
QDateTime dateTime;
QString dt;
if (m_settings.m_aosDateTime.isValid()) {
dateTime = m_settings.m_aosDateTime;
} else {
dateTime = QDateTime::currentDateTime();
}
dt = dateTime.toString("yyyyMMdd_hhmm");
QString sat = m_satelliteName;
sat.replace(" ", "_");
if (m_settings.m_saveCombined)
{
filename = QString("apt_%1_%2.png").arg(sat).arg(dt);
prependPath(filename);
if (!image.save(filename)) {
qCritical() << "Failed to save APT image to: " << filename;
}
}
QImage chA = extractImage(image, APTDemodSettings::CHANNEL_A);
QImage chB = extractImage(image, APTDemodSettings::CHANNEL_B);
if (m_settings.m_saveSeparate)
{
filename = QString("apt_%1_%2_cha.png").arg(sat).arg(dt);
prependPath(filename);
if (!chA.save(filename)) {
qCritical() << "Failed to save APT image to: " << filename;
}
filename = QString("apt_%1_%2_chb.png").arg(sat).arg(dt);
prependPath(filename);
if (!chB.save(filename)) {
qCritical() << "Failed to save APT image to: " << filename;
}
}
if (m_settings.m_saveProjection)
{
filename = QString("apt_%1_%2_cha_eqi_cylindrical.png").arg(sat).arg(dt);
prependPath(filename);
QImage chAProj = projectImage(chA);
if (!chAProj.save(filename)) {
qCritical() << "Failed to save APT image to: " << filename;
}
filename = QString("apt_%1_%2_chb_eqi_cylindrical.png").arg(sat).arg(dt);
prependPath(filename);
QImage chBProj = projectImage(chB);
if (!chBProj.save(filename)) {
qCritical() << "Failed to save APT image to: " << filename;
}
}
}
}
void APTDemodImageWorker::copyImage(apt_image_t *dst, apt_image_t *src)
{
dst->nrow = src->nrow;
dst->chA = src->chA;
dst->chB = src->chB;
for (int i = 0; i < src->nrow; i++) {
std::copy(src->prow[i], src->prow[i] + APT_PROW_WIDTH, dst->prow[i]);
}
}
uchar APTDemodImageWorker::roundAndClip(float p)
{
int q = (int) round(p);
q = q > 255 ? 255 : q < 0 ? 0 : q;
return q;
}