mirror of
https://github.com/f4exb/sdrangel.git
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711 lines
20 KiB
C++
711 lines
20 KiB
C++
///////////////////////////////////////////////////////////////////////////////////
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// Copyright (C) 2022 Jon Beniston, M7RCE <jon@beniston.com> //
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// //
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// Based on code and docs by einergehtnochrein, rs1729 and bazjo //
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// //
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// This program is free software; you can redistribute it and/or modify //
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// it under the terms of the GNU General Public License as published by //
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// the Free Software Foundation as version 3 of the License, or //
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// (at your option) any later version. //
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// //
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// This program is distributed in the hope that it will be useful, //
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// but WITHOUT ANY WARRANTY; without even the implied warranty of //
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the //
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// GNU General Public License V3 for more details. //
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// //
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// You should have received a copy of the GNU General Public License //
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// along with this program. If not, see <http://www.gnu.org/licenses/>. //
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///////////////////////////////////////////////////////////////////////////////////
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#include <QDateTime>
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#include <QVector3D>
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#include "util/radiosonde.h"
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#include "util/coordinates.h"
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RS41Frame::RS41Frame(const QByteArray ba) :
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m_statusValid(false),
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m_batteryVoltage(0.0),
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m_pcbTemperature(0),
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m_humiditySensorHeating(0),
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m_transmitPower(0),
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m_maxSubframeNumber(0),
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m_subframeNumber(0),
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m_measValid(false),
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m_gpsInfoValid(false),
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m_posValid(false),
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m_latitude(0.0),
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m_longitude(0.0),
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m_height(0.0),
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m_bytes(ba),
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m_pressureCalibrated(false),
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m_temperatureCalibrated(false),
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m_humidityTemperatureCalibrated(false),
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m_humidityCalibrated(false)
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{
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int length = getFrameLength(ba[RS41_OFFSET_FRAME_TYPE]);
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for (int i = RS41_OFFSET_BLOCK_0; i < length; )
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{
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uint8_t blockID = ba[i+0];
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uint8_t blockLength = ba[i+1];
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switch (blockID)
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{
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case RS41_ID_STATUS:
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decodeStatus(ba.mid(i+2, blockLength));
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break;
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case RS41_ID_MEAS:
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decodeMeas(ba.mid(i+2, blockLength));
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break;
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case RS41_ID_GPSINFO:
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decodeGPSInfo(ba.mid(i+2, blockLength));
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break;
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case RS41_ID_GPSRAW:
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break;
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case RS41_ID_GPSPOS:
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decodeGPSPos(ba.mid(i+2, blockLength));
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break;
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case RS41_ID_EMPTY:
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break;
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}
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i += 2 + blockLength + 2; // ID, length, data, CRC
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}
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}
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QString RS41Frame::toHex()
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{
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return m_bytes.toHex();
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}
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uint16_t RS41Frame::getUInt16(const QByteArray ba, int offset) const
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{
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return (ba[offset] & 0xff)
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| ((ba[offset+1] & 0xff) << 8);
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}
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uint32_t RS41Frame::getUInt24(const QByteArray ba, int offset) const
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{
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return (ba[offset] & 0xff)
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| ((ba[offset+1] & 0xff) << 8)
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| ((ba[offset+2] & 0xff) << 16);
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}
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uint32_t RS41Frame::getUInt32(const QByteArray ba, int offset) const
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{
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return (ba[offset] & 0xff)
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| ((ba[offset+1] & 0xff) << 8)
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| ((ba[offset+2] & 0xff) << 16)
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| ((ba[offset+3] & 0xff) << 24);
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}
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void RS41Frame::decodeStatus(const QByteArray ba)
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{
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m_statusValid = true;
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m_frameNumber = getUInt16(ba, 0);
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m_serial = QString(ba.mid(0x2, 8));
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m_batteryVoltage = (ba[0xa] & 0xff) / 10.0;
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QStringList phases = {"Ground", "Ascent", "0x2", "Descent"};
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int phase = ba[0xd] & 0x3;
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m_flightPhase = phases[phase];
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m_batteryStatus = (ba[0xe] & 0x10) == 0 ? "OK" : "Low";
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m_pcbTemperature = (ba[0x10] & 0xff);
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m_humiditySensorHeating = getUInt16(ba, 0x13);
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m_transmitPower = ba[0x15] & 0xff;
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m_maxSubframeNumber = ba[0x16] & 0xff;
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m_subframeNumber = ba[0x17] & 0xff;
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m_subframe = ba.mid(0x18, 16);
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}
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void RS41Frame::decodeMeas(const QByteArray ba)
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{
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m_measValid = true;
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m_tempMain = getUInt24(ba, 0x0);
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m_tempRef1 = getUInt24(ba, 0x3);
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m_tempRef2 = getUInt24(ba, 0x6);
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m_humidityMain = getUInt24(ba, 0x9);
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m_humidityRef1 = getUInt24(ba, 0xc);
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m_humidityRef2 = getUInt24(ba, 0xf);
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m_humidityTempMain = getUInt24(ba, 0x12);
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m_humidityTempRef1 = getUInt24(ba, 0x15);
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m_humidityTempRef2 = getUInt24(ba, 0x18);
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m_pressureMain = getUInt24(ba, 0x1b);
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m_pressureRef1 = getUInt24(ba, 0x1e);
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m_pressureRef2 = getUInt24(ba, 0x21);
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m_pressureTemp = getUInt16(ba, 0x26) / 100.0f;
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}
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void RS41Frame::decodeGPSInfo(const QByteArray ba)
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{
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m_gpsInfoValid = true;
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uint16_t gpsWeek = getUInt16(ba, 0x0);
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uint32_t gpsTimeOfWeek = getUInt32(ba, 0x2); // Milliseconds
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QDateTime epoch(QDate(1980, 1, 6), QTime(0, 0, 0), Qt::OffsetFromUTC, 18); // GPS doesn't count leap seconds
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m_gpsDateTime = epoch.addDays(gpsWeek*7).addMSecs(gpsTimeOfWeek);
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}
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void RS41Frame::decodeGPSPos(const QByteArray ba)
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{
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m_satellitesUsed = ba[0x12] & 0xff;
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if (m_satellitesUsed > 0)
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{
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m_posValid = true;
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int32_t ecefX = (int32_t)getUInt32(ba, 0x0);
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int32_t ecefY = (int32_t)getUInt32(ba, 0x4);
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int32_t ecefZ = (int32_t)getUInt32(ba, 0x8);
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// Convert cm to m
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// Convert to latitude, longitude and altitude
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Coordinates::ecefToGeodetic(ecefX / 100.0, ecefY / 100.0, ecefZ / 100.0, m_latitude, m_longitude, m_height);
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int32_t velX = (int16_t)getUInt16(ba, 0xc);
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int32_t velY = (int16_t)getUInt16(ba, 0xe);
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int32_t velZ = (int16_t)getUInt16(ba, 0x10);
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// Convert cm/s to m/s
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// Calculate speed / heading
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Coordinates::ecefVelToSpeedHeading(m_latitude, m_longitude, velX / 100.0, velY / 100.0, velZ / 100.0, m_speed, m_verticalRate, m_heading);
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}
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}
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// Find the water vapor saturation pressure for a given temperature.
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float waterVapourSaturationPressure(float tCelsius)
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{
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// Convert to Kelvin
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float T = tCelsius + 273.15f;
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// Correction
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T = - 0.4931358f
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+ (1.0f + 4.6094296e-3f) * T
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- 1.3746454e-5f * T * T
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+ 1.2743214e-8f * T * T * T;
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// Hyland and Wexler equation
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float p = expf(-5800.2206f / T
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+ 1.3914993f
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+ 6.5459673f * logf(T)
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- 4.8640239e-2f * T
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+ 4.1764768e-5f * T * T
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- 1.4452093e-8f * T * T * T);
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// Scale result to hPa
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return p / 100.0f;
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}
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float calcT(int f, int f1, int f2, float r1, float r2, float *poly, float *cal)
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{
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/*float g = (float)(f2-f1) / (r2-r1); // gain
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float Rb = (f1*r2-f2*r1) / (float)(f2-f1); // offset
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float Rc = f/g - Rb;
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float R = Rc * cal[0];
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float T = (poly[0] + poly[1]*R + poly[2]*R*R + cal[1])*(1.0 + cal[2]);
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return T;
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*/
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// Convert integer measurement to scale factor
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float s = (f-f1)/(float)(f2-f1);
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// Calculate resistance (scale between two reference resistors)
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float rUncal = r1 + (r2 - r1) * s;
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float r = rUncal * cal[0];
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// Convert resistance to temperature
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float tUncal = poly[0] + poly[1]*r + poly[2]*r*r;
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// Correct temperature (5th order polynomial)
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float tCal = 0.0f;
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for (int i = 6; i > 0; i--)
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{
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tCal *= tUncal;
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tCal += cal[i];
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}
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tCal += tUncal;
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return tCal;
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}
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float calcU(int cInt, int cMin, int cMax, float c1, float c2, float T, float HT, float *capCal, float *matrixCal)
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{
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//qDebug() << "cInt " << cInt << " cMin " << cMin << " cMax " << cMax << " c1 " << c1 << " c2 " << c2 << " T " << T << " HT " << HT << " capCal[0] " << capCal[0] << " capCal[1] " << capCal[1];
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/*
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float a0 = 7.5f;
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float a1 = 350.0f / capCal[0];
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float fh = (cInt-cMin) / (float)(cMax-cMin);
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float rh = 100.0f * (a1*fh - a0);
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float T0 = 0.0f;
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float T1 = -25.0f;
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rh += T0 - T/5.5;
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if (T < T1) {
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rh *= 1.0 + (T1-T)/90.0;
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}
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if (rh < 0.0) {
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rh = 0.0;
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}
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if (rh > 100.0) {
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rh = 100.0;
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}
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if (T < -273.0) {
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rh = -1.0;
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}
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qDebug() << "RH old method: " << rh; */
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// Convert integer measurement to scale factor
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float s = (cInt - cMin) / (float)(cMax-cMin);
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// Calculate capacitance (scale between two reference caps)
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float cUncal = c1 + (c2 - c1) * s;
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float cCal = (cUncal / capCal[0] - 1.0f) * capCal[1];
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float uUncal = 0.0f;
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float t = (HT - 20.0f) / 180.0f;
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float f1 = 1.0f;
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for (int i = 0; i < 7; i++)
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{
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float f2 = 1.0;
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for (int j = 0; j < 6; j++)
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{
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uUncal += f1 * f2 * matrixCal[i*6+j];
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f2 *= t;
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}
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f1 *= cCal;
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}
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// Adjust for difference in outside air temperature and the humidty sensor temperature
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float uCal = uUncal * waterVapourSaturationPressure(T) / waterVapourSaturationPressure(HT);
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// Ensure within range of 0..100%
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uCal = std::min(100.0f, uCal);
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uCal = std::max(0.0f, uCal);
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return uCal;
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}
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float calcP(int f, int f1, int f2, float pressureTemp, float *cal)
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{
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// Convert integer measurement to scale factor
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float s = (f-f1) / (float)(f2-f1);
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float t = pressureTemp;
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float t2 = t * t;
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float t3 = t2 * t;
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float poly[6];
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poly[0] = cal[0] + cal[7] * t + cal[11] * t2 + cal[15] * t3;
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poly[1] = cal[1] + cal[8] * t + cal[12] * t2 + cal[16] * t3;
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poly[2] = cal[2] + cal[9] * t + cal[13] * t2 + cal[17] * t3;
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poly[3] = cal[3] + cal[10] * t + cal[14] * t2;
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poly[4] = cal[4];
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poly[5] = cal[5];
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float p = cal[6] / s;
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float p2 = p * p;
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float p3 = p2 * p;
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float p4 = p3 * p;
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float p5 = p4 * p;
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float pCal = poly[0] + poly[1] * p + poly[2] * p2 + poly[3] * p3 + poly[4] * p4 + poly[5] * p5;
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return pCal;
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}
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float RS41Frame::getPressureFloat(const RS41Subframe *subframe)
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{
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if (!m_pressureCalibrated) {
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calcPressure(subframe);
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}
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return m_pressure;
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}
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QString RS41Frame::getPressureString(const RS41Subframe *subframe)
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{
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if (!m_pressureCalibrated) {
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calcPressure(subframe);
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}
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return m_pressureString;
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}
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float RS41Frame::getTemperatureFloat(const RS41Subframe *subframe)
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{
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if (!m_temperatureCalibrated) {
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calcTemperature(subframe);
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}
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return m_temperature;
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}
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QString RS41Frame::getTemperatureString(const RS41Subframe *subframe)
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{
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if (!m_temperatureCalibrated) {
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calcTemperature(subframe);
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}
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return m_temperatureString;
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}
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void RS41Frame::calcPressure(const RS41Subframe *subframe)
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{
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float cal[18];
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if (m_pressureMain == 0)
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{
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m_pressure = 0.0f;
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m_pressureString = "";
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return;
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}
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m_pressureCalibrated = subframe->getPressureCal(cal);
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m_pressure = calcP(m_pressureMain, m_pressureRef1, m_pressureRef2, m_pressureTemp, cal);
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// RS41 pressure resolution of 0.01hPa
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m_pressureString = QString::number(m_pressure, 'f', 2);
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if (!m_pressureCalibrated) {
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m_pressureString = m_pressureString + "U"; // U for uncalibrated
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}
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}
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void RS41Frame::calcTemperature(const RS41Subframe *subframe)
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{
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float r1, r2;
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float poly[3];
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float cal[7];
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if (m_tempMain == 0)
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{
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m_temperature = 0.0f;
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m_temperatureString = "";
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return;
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}
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m_temperatureCalibrated = subframe->getTempCal(r1, r2, poly, cal);
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m_temperature = calcT(m_tempMain, m_tempRef1, m_tempRef2,
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r1, r2,
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poly, cal);
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// RS41 temperature resolution of 0.01C
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m_temperatureString = QString::number(m_temperature, 'f', 2);
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if (!m_temperatureCalibrated) {
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m_temperatureString = m_temperatureString + "U"; // U for uncalibrated
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}
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}
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float RS41Frame::getHumidityTemperatureFloat(const RS41Subframe *subframe)
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{
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if (!m_humidityTemperatureCalibrated) {
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calcHumidityTemperature(subframe);
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}
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return m_humidityTemperature;
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}
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void RS41Frame::calcHumidityTemperature(const RS41Subframe *subframe)
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{
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float r1, r2;
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float poly[3];
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float cal[7];
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if (m_humidityTempMain == 0)
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{
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m_humidityTemperature = 0.0f;
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return;
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}
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m_humidityTemperatureCalibrated = subframe->getHumidityTempCal(r1, r2, poly, cal);
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m_humidityTemperature = calcT(m_humidityTempMain, m_humidityTempRef1, m_humidityTempRef2,
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r1, r2,
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poly, cal);
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}
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float RS41Frame::getHumidityFloat(const RS41Subframe *subframe)
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{
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if (!m_humidityCalibrated) {
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calcHumidity(subframe);
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}
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return m_humidity;
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}
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QString RS41Frame::getHumidityString(const RS41Subframe *subframe)
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{
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if (!m_humidityCalibrated) {
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calcHumidity(subframe);
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}
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return m_humidityString;
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}
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void RS41Frame::calcHumidity(const RS41Subframe *subframe)
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{
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float c1, c2;
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float capCal[2];
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float calMatrix[7*6];
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if (m_humidityMain == 0)
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{
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m_humidity = 0.0f;
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m_humidityString = "";
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return;
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}
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float temperature = getTemperatureFloat(subframe);
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float humidityTemperature = getHumidityTemperatureFloat(subframe);
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bool humidityCalibrated = subframe->getHumidityCal(c1, c2, capCal, calMatrix);
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m_humidityCalibrated = m_temperatureCalibrated && m_humidityTemperatureCalibrated && humidityCalibrated;
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m_humidity = calcU(m_humidityMain, m_humidityRef1, m_humidityRef2,
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c1, c2,
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temperature, humidityTemperature,
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capCal, calMatrix);
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// RS41 humidity resolution of 0.1%
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m_humidityString = QString::number(m_humidity, 'f', 1);
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if (!m_humidityCalibrated) {
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m_humidityString = m_humidityString + "U"; // U for uncalibrated
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}
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}
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RS41Frame* RS41Frame::decode(const QByteArray ba)
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{
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return new RS41Frame(ba);
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}
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int RS41Frame::getFrameLength(int frameType)
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{
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return frameType == RS41_FRAME_STD ? RS41_LENGTH_STD : RS41_LENGTH_EXT;
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}
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RS41Subframe::RS41Subframe() :
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m_subframe(51*16, (char)0)
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{
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for (int i = 0; i < 51; i++) {
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m_subframeValid[i] = false;
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}
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}
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// Update subframe with subframe data from received message
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void RS41Subframe::update(RS41Frame *message)
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{
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m_subframeValid[message->m_subframeNumber] = true;
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int offset = message->m_subframeNumber * 16;
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for (int i = 0; i < 16; i++) {
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m_subframe[offset+i] = message->m_subframe[i];
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}
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}
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// Indicate if we have all the required temperature calibration data
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bool RS41Subframe::hasTempCal() const
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{
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return m_subframeValid[3] && m_subframeValid[4] && m_subframeValid[5] && m_subframeValid[6] && m_subframeValid[7];
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}
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// Get temperature calibration data
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// r1, r2 - Temperature reference resistances (Ohms)
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// poly - Resistance to temperature 2nd order polynomial
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bool RS41Subframe::getTempCal(float &r1, float &r2, float *poly, float *cal) const
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{
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if (hasTempCal())
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{
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r1 = getFloat(0x3d);
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r2 = getFloat(0x41);
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for (int i = 0; i < 3; i++) {
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poly[i] = getFloat(0x4d + i * 4);
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}
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for (int i = 0; i < 7; i++) {
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cal[i] = getFloat(0x59 + i * 4);
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}
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return true;
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}
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else
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{
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// Use default values
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r1 = 750.0f;
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r2 = 1100.0f;
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poly[0] = -243.9108f;
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poly[1] = 0.187654f;
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poly[2] = 8.2e-06f;
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cal[0] = 1.279928f;
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for (int i = 1; i < 7; i++) {
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cal[i] = 0.0f;
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}
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return false;
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}
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}
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// Indicate if we have all the required humidty calibration data
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bool RS41Subframe::hasHumidityCal() const
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{
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return m_subframeValid[4] && m_subframeValid[7]
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&& m_subframeValid[8] && m_subframeValid[9] && m_subframeValid[0xa] && m_subframeValid[0xb]
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&& m_subframeValid[0xc] && m_subframeValid[0xd] && m_subframeValid[0xe] && m_subframeValid[0xf]
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&& m_subframeValid[0x10] && m_subframeValid[0x11] && m_subframeValid[0x12];
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}
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// Get humidty calibration data
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bool RS41Subframe::getHumidityCal(float &c1, float &c2, float *capCal, float *calMatrix) const
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{
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if (hasHumidityCal())
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{
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c1 = getFloat(0x45);
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c2 = getFloat(0x49);
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for (int i = 0; i < 2; i++) {
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capCal[i] = getFloat(0x75 + i * 4);
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}
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for (int i = 0; i < 7*6; i++) {
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calMatrix[i] = getFloat(0x7d + i * 4);
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}
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return true;
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}
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else
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{
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// Use default values
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c1 = 0.0f;
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c2 = 47.0f;
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capCal[0] = 45.9068f;
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capCal[1] = 4.92924f;
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static const float calMatrixDefault[7*6] = {
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-0.002586f, -2.24367f, 9.92294f, -3.61913f, 54.3554f, -93.3012f,
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51.7056f, 38.8709f, 209.437f, -378.437f, 9.17326f, 19.5301f,
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150.257f, -150.907f, -280.315f, 182.293f, 3247.39f, 4083.65f,
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-233.568f, 345.375f, 200.217f, -388.246f, -3617.66f, 0.0f,
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225.841f, -233.051f, 0.0f, 0.0f, 0.0f, 0.0f,
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-93.0635f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f,
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0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f
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};
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std::copy(calMatrixDefault, calMatrixDefault + 7*6, calMatrix);
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return false;
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}
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}
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// Indicate if we have all the required humidty temperature sensor calibration data
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bool RS41Subframe::hasHumidityTempCal() const
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{
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return m_subframeValid[3] && m_subframeValid[4] && m_subframeValid[0x12] && m_subframeValid[0x13] && m_subframeValid[0x14];
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}
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// Get humidty temperature sensor calibration data
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bool RS41Subframe::getHumidityTempCal(float &r1, float &r2, float *poly, float *cal) const
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{
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if (hasHumidityTempCal())
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{
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r1 = getFloat(0x3d);
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r2 = getFloat(0x41);
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for (int i = 0; i < 3; i++) {
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poly[i] = getFloat(0x125 + i * 4);
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}
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for (int i = 0; i < 7; i++) {
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cal[i] = getFloat(0x131 + i * 4);
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}
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return true;
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}
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else
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{
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// Use default values
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r1 = 750.0f;
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r2 = 1100.0f;
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poly[0] = -243.9108f;
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poly[1] = 0.187654f;
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poly[2] = 8.2e-06f;
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cal[0] = 1.279928f;
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for (int i = 1; i < 7; i++) {
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cal[i] = 0.0f;
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}
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return false;
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}
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}
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// Indicate if we have all the required pressure calibration data
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bool RS41Subframe::hasPressureCal() const
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{
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return m_subframeValid[0x25] && m_subframeValid[0x26] && m_subframeValid[0x27]
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&& m_subframeValid[0x28] && m_subframeValid[0x29] && m_subframeValid[0x2a];
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}
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// Get pressure calibration data
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bool RS41Subframe::getPressureCal(float *cal) const
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{
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if (hasPressureCal())
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{
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for (int i = 0; i < 18; i++) {
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cal[i] = getFloat(0x25e + i * 4);
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}
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return true;
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}
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else
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{
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// Use default values - TODO: Need to obtain from inflight device
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for (int i = 0; i < 18; i++) {
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cal[i] = 0.0f;
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}
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return false;
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}
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}
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// Get type of RS41. E.g. "RS41-SGP"
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QString RS41Subframe::getType() const
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{
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if (m_subframeValid[0x21] & m_subframeValid[0x22])
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{
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return QString(m_subframe.mid(0x218, 10)).trimmed();
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}
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else
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{
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return "RS41";
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}
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}
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// Get transmission frequency in MHz
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QString RS41Subframe::getFrequencyMHz() const
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{
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if (m_subframeValid[0])
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{
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uint8_t lower = m_subframe[2] & 0xff;
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uint8_t upper = m_subframe[3] & 0xff;
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float freq = 400.0 + (upper + (lower / 255.0)) * 0.04;
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return QString::number(freq, 'f', 3);
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}
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else
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{
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return "";
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}
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}
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QString RS41Subframe::getBurstKillStatus() const
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{
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if (m_subframeValid[2])
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|
{
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uint8_t status = m_subframe[0x2b];
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return status == 0 ? "Inactive" : "Active";
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}
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else
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|
{
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|
return "";
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}
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}
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// Seconds until power-off once active
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QString RS41Subframe::getBurstKillTimer() const
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|
{
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if (m_subframeValid[0x31])
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|
{
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uint16_t secs = getUInt16(0x316);
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|
QTime t(0, 0, 0);
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|
t = t.addSecs(secs);
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|
return t.toString("hh:mm:ss");
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|
}
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|
else
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|
{
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|
return "";
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|
}
|
|
}
|
|
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uint16_t RS41Subframe::getUInt16(int offset) const
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|
{
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return (m_subframe[offset] & 0xff) | ((m_subframe[offset+1] & 0xff) << 8);
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}
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|
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float RS41Subframe::getFloat(int offset) const
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|
{
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|
float f;
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|
// Assumes host is little endian with 32-bit float
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|
memcpy(&f, m_subframe.data() + offset, 4);
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|
return f;
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|
}
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