/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2021-2022 Edouard Griffiths, F4EXB // // Copyright (C) 2021-2024 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 . // /////////////////////////////////////////////////////////////////////////////////// #include #include #include "dsp/dspengine.h" #include "dsp/scopevis.h" #include "util/db.h" #include "maincore.h" #include "radioclock.h" #include "radioclocksink.h" RadioClockSink::RadioClockSink(RadioClock *radioClock) : m_scopeSink(nullptr), m_radioClock(radioClock), m_channelSampleRate(RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE), m_channelFrequencyOffset(0), m_magsq(0.0), m_magsqSum(0.0), m_magsqPeak(0.0), m_magsqCount(0), m_messageQueueToChannel(nullptr), m_data(0), m_prevData(0), m_sample(0), m_lowCount(0), m_highCount(0), m_periodCount(0), m_gotMinuteMarker(false), m_second(0), m_dst(RadioClockSettings::UNKNOWN), m_zeroCount(0), m_sampleBufferIndex(0), m_gotMarker(false) { m_phaseDiscri.setFMScaling(RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE / (2.0f * 20.0/M_PI)); applySettings(m_settings, true); applyChannelSettings(m_channelSampleRate, m_channelFrequencyOffset, true); for (int i = 0; i < RadioClockSettings::m_scopeStreams; i++) { m_sampleBuffer[i].resize(m_sampleBufferSize); } } RadioClockSink::~RadioClockSink() { } void RadioClockSink::setScopeSink(ScopeVis* scopeSink) { m_scopeSink = scopeSink; } void RadioClockSink::sampleToScope(Complex sample) { if (m_scopeSink) { m_sampleBuffer[0][m_sampleBufferIndex] = sample; m_sampleBuffer[1][m_sampleBufferIndex] = Complex(m_magsq, 0.0f); m_sampleBuffer[2][m_sampleBufferIndex] = Complex(m_threshold, 0.0f); m_sampleBuffer[3][m_sampleBufferIndex] = Complex(m_fmDemodMovingAverage.asDouble(), 0.0f); m_sampleBuffer[4][m_sampleBufferIndex] = Complex(m_data, 0.0f); m_sampleBuffer[5][m_sampleBufferIndex] = Complex(m_sample, 0.0f); m_sampleBuffer[6][m_sampleBufferIndex] = Complex(m_gotMinuteMarker, 0.0f); m_sampleBuffer[7][m_sampleBufferIndex] = Complex(m_gotMarker, 0.0f); m_sampleBufferIndex++; if (m_sampleBufferIndex == m_sampleBufferSize) { std::vector vbegin; for (int i = 0; i < RadioClockSettings::m_scopeStreams; i++) { vbegin.push_back(m_sampleBuffer[i].begin()); } m_scopeSink->feed(vbegin, m_sampleBufferSize); m_sampleBufferIndex = 0; } } } void RadioClockSink::feed(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end) { Complex ci; for (SampleVector::const_iterator it = begin; it != end; ++it) { Complex c(it->real(), it->imag()); c *= m_nco.nextIQ(); if (m_interpolatorDistance < 1.0f) // interpolate { while (!m_interpolator.interpolate(&m_interpolatorDistanceRemain, c, &ci)) { processOneSample(ci); m_interpolatorDistanceRemain += m_interpolatorDistance; } } else // decimate { if (m_interpolator.decimate(&m_interpolatorDistanceRemain, c, &ci)) { processOneSample(ci); m_interpolatorDistanceRemain += m_interpolatorDistance; } } } } // Extract binary-coded decimal from time code - LSB first int RadioClockSink::bcd(int firstBit, int lastBit) { const int vals[] = {1, 2, 4, 8, 10, 20, 40, 80}; int idx = 0; int val = 0; for (int i = firstBit; i <= lastBit; i++) { if (m_timeCode[i]) { val += vals[idx]; } idx++; } return val; } // Extract binary-coded decimal from time code - MSB first int RadioClockSink::bcdMSB(int firstBit, int lastBit, int skipBit1, int skipBit2) { const int vals[] = {1, 2, 4, 8, 10, 20, 40, 80, 100, 200}; int idx = 0; int val = 0; for (int i = lastBit; i >= firstBit; i--) { if ((i != skipBit1) && (i != skipBit2)) { if (m_timeCode[i]) { val += vals[idx]; } idx++; } } return val; } // XOR bits together for parity check int RadioClockSink::xorBits(int firstBit, int lastBit) { int x = 0; for (int i = firstBit; i <= lastBit; i++) { x ^= m_timeCode[i]; } return x; } bool RadioClockSink::evenParity(int firstBit, int lastBit, int parityBit) { return xorBits(firstBit, lastBit) == parityBit; } bool RadioClockSink::oddParity(int firstBit, int lastBit, int parityBit) { return xorBits(firstBit, lastBit) != parityBit; } // German DCF77 // https://en.wikipedia.org/wiki/DCF77 void RadioClockSink::dcf77() { // DCF77 reduces carrier by -16.5dB m_threshold = m_thresholdMovingAverage.asDouble() * m_linearThreshold; // xdB below average m_data = m_magsq > m_threshold; // Look for minute marker - 59th second carrier is held high if ((m_data == 0) && (m_prevData == 1)) { if ( (m_highCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 2) && (m_highCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 1.6) && (m_lowCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.3) && (m_lowCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.1) ) { qDebug() << "RadioClockSink::dcf77 - Minute marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount; if (getMessageQueueToChannel() && !m_gotMinuteMarker) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Got minute marker")); } m_periodCount = 0; m_second = 0; m_gotMinuteMarker = true; m_secondMarkers = 1; } m_lowCount = 0; } else if ((m_data == 1) && (m_prevData == 0)) { m_highCount = 0; } else if (m_data == 1) { m_highCount++; } else if (m_data == 0) { m_lowCount++; } m_sample = false; if (m_gotMinuteMarker) { m_periodCount++; if (m_periodCount == 50) { // Check we get second marker m_secondMarkers += m_data == 0; // If we see too many 1s instead of 0s, assume we've lost the signal if ((m_second > 10) && (m_secondMarkers / m_second < 0.7)) { qDebug() << "RadioClockSink::dcf77 - Lost lock: " << m_secondMarkers << m_second; m_gotMinuteMarker = false; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } m_sample = true; } else if (m_periodCount == 150) { // Get data for timecode m_timeCode[m_second] = !m_data; // No carrier = 1, carrier = 0 m_sample = true; } else if (m_periodCount == 950) { if (m_second == 59) { // Decode timecode to a time and date int minute = bcd(21, 27); int hour = bcd(29, 34); int day = bcd(36, 41); int month = bcd(45, 49); int year = 2000 + bcd(50, 57); QString parityError; if (!evenParity(21, 27, m_timeCode[28])) { parityError = "Minute parity error"; } if (!evenParity(29, 34, m_timeCode[35])) { parityError = "Hour parity error"; } if (!evenParity(36, 57, m_timeCode[58])) { parityError= "Data parity error"; } // Daylight savings if (m_timeCode[17] && m_timeCode[16]) { m_dst = RadioClockSettings::ENDING; } else if (m_timeCode[17]) { m_dst = RadioClockSettings::IN_EFFECT; } else if (m_timeCode[18] && m_timeCode[16]) { m_dst = RadioClockSettings::STARTING; } else if (m_timeCode[18]) { m_dst = RadioClockSettings::NOT_IN_EFFECT; } else { m_dst = RadioClockSettings::UNKNOWN; } if (parityError.isEmpty()) { // Bit 17 indicates CEST rather than CET m_dateTime = QDateTime(QDate(year, month, day), QTime(hour, minute), Qt::OffsetFromUTC, m_timeCode[17] ? 2*3600 : 3600); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("OK")); } } else { m_dateTime = m_dateTime.addSecs(1); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create(parityError)); } } m_second = 0; } else { m_second++; m_dateTime = m_dateTime.addSecs(1); } if (getMessageQueueToChannel()) { RadioClock::MsgDateTime *msg = RadioClock::MsgDateTime::create(m_dateTime, m_dst); getMessageQueueToChannel()->push(msg); } } else if (m_periodCount == 1000) { m_periodCount = 0; } } m_prevData = m_data; } // French TDF 162kHz // https://en.wikipedia.org/wiki/TDF_time_signal // Uses phase modulation, rather than OOK void RadioClockSink::tdf(Complex &ci) { // FM demodulation double magsqRaw; Real deviation; Real fmDemod = m_phaseDiscri.phaseDiscriminatorDelta(ci, magsqRaw, deviation); // Filter m_fmDemodMovingAverage(fmDemod); // Ternary encoding Real avg = m_fmDemodMovingAverage.asDouble(); if (avg >= 0.5) { m_data = 1; } else if (avg <= -0.5) { m_data = -1; } else { m_data = 0; } // Look for minute marker - 59th second is not phase modulated if ((m_data == 1) && (m_prevData == 0)) { if ( (m_zeroCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 2) && (m_zeroCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 1) ) { qDebug() << "RadioClockSink::tdf - Minute marker: (zero " << m_zeroCount << ") prev period " << m_periodCount; if (getMessageQueueToChannel() && !m_gotMinuteMarker) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Got minute marker")); } m_periodCount = 0; m_second = 0; m_gotMinuteMarker = true; m_secondMarkers = 1; } } else if ((m_data == 0) && (m_prevData != 0)) { m_zeroCount = 0; } else if (m_data == 0) { m_zeroCount++; } m_sample = false; if (m_gotMinuteMarker) { m_periodCount++; if (m_periodCount == 12) { m_bits[0] = m_data; m_sample = true; } else if (m_periodCount == 12+50) { m_bits[1] = m_data; m_sample = true; } else if (m_periodCount == 12+100) { m_bits[2] = m_data; m_sample = true; } else if (m_periodCount == 12+150) { m_bits[3] = m_data; m_sample = true; // Check we got second marker m_secondMarkers += ((m_bits[0] == 1) && (m_bits[1] == -1)); // If too many second markers are missing, assume we've lost the signal if ((m_second > 10) && (m_secondMarkers / m_second < 0.7)) { qDebug() << "RadioClockSink::tdf - Lost lock: " << m_secondMarkers << m_second; m_gotMinuteMarker = false; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } // No phase modulation from 50ms to 150ms is 0, pos then neg is 1 if ((m_bits[2] == 0) && (m_bits[3] == 0)) { m_timeCode[m_second] = 0; } else if ((m_bits[2] == 1) && (m_bits[3] == -1)) { m_timeCode[m_second] = 1; } else { //qDebug() << "Unexpected modulation " << m_second; } } else if (m_periodCount == 950) { if (m_second == 59) { // Decode timecode to time and date int minute = bcd(21, 27); int hour = bcd(29, 34); int day = bcd(36, 41); int month = bcd(45, 49); int year = 2000 + bcd(50, 57); // Daylight savings if (m_timeCode[17] && m_timeCode[16]) { m_dst = RadioClockSettings::ENDING; } else if (m_timeCode[17]) { m_dst = RadioClockSettings::IN_EFFECT; } else if (m_timeCode[18] && m_timeCode[16]) { m_dst = RadioClockSettings::STARTING; } else if (m_timeCode[18]) { m_dst = RadioClockSettings::NOT_IN_EFFECT; } else { m_dst = RadioClockSettings::UNKNOWN; } QString parityError; if (!evenParity(21, 27, m_timeCode[28])) { parityError = "Minute parity error"; } if (!evenParity(29, 34, m_timeCode[35])) { parityError = "Hour parity error"; } if (!evenParity(36, 57, m_timeCode[58])) { parityError= "Data parity error"; } if (parityError.isEmpty()) { // Bit 17 indicates CEST rather than CET m_dateTime = QDateTime(QDate(year, month, day), QTime(hour, minute), Qt::OffsetFromUTC, m_timeCode[17] ? 2*3600 : 3600); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("OK")); } } else { m_dateTime = m_dateTime.addSecs(1); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create(parityError)); } } m_second = 0; } else { m_second++; m_dateTime = m_dateTime.addSecs(1); } if (getMessageQueueToChannel()) { RadioClock::MsgDateTime *msg = RadioClock::MsgDateTime::create(m_dateTime, m_dst); getMessageQueueToChannel()->push(msg); } } else if (m_periodCount == 1000) { m_periodCount = 0; } } m_prevData = m_data; } // UK MSF 60kHz // https://www.npl.co.uk/products-services/time-frequency/msf-radio-time-signal/msf_time_date_code void RadioClockSink::msf60() { m_threshold = m_thresholdMovingAverage.asDouble() * m_linearThreshold; // xdB below average m_data = m_magsq > m_threshold; // Look for minute marker - 500ms low, then 500ms high if ((m_data == 0) && (m_prevData == 1)) { if ( (m_highCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.6) && (m_highCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.4) && (m_lowCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.6) && (m_lowCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.4) ) { qDebug() << "RadioClockSink::msf60 - Minute marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount; if (getMessageQueueToChannel() && !m_gotMinuteMarker) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Got minute marker")); } m_periodCount = 0; m_second = 1; m_gotMinuteMarker = true; m_secondMarkers = 1; } m_lowCount = 0; } else if ((m_data == 1) && (m_prevData == 0)) { m_highCount = 0; } else if (m_data == 1) { m_highCount++; } else if (m_data == 0) { m_lowCount++; } m_sample = false; if (m_gotMinuteMarker) { m_periodCount++; if (m_periodCount == 50) { // Check we get second marker m_secondMarkers += m_data == 0; // If we see too many 1s instead of 0s, assume we've lost the signal if ((m_second > 10) && (m_secondMarkers / m_second < 0.7)) { qDebug() << "RadioClockSink::msf60 - Lost lock: " << m_secondMarkers << m_second; m_gotMinuteMarker = false; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } m_sample = true; } else if (m_periodCount == 150) { // Get data bit A for timecode m_timeCode[m_second] = !m_data; // No carrier = 1, carrier = 0 m_sample = true; } else if (m_periodCount == 250) { // Get data bit B for timecode m_timeCodeB[m_second] = !m_data; m_sample = true; } else if (m_periodCount == 950) { if (m_second == 59) { // Decode timecode to time and date int minute = bcdMSB(45, 51); int hour = bcdMSB(39, 44); int day = bcdMSB(30, 35); //int dayOfWeek = bcdMSB(36, 38); int month = bcdMSB(25, 29); int year = 2000 + bcdMSB(17, 24); // Daylight savings if (m_timeCodeB[58] && m_timeCodeB[53]) { m_dst = RadioClockSettings::ENDING; } else if (m_timeCodeB[58]) { m_dst = RadioClockSettings::IN_EFFECT; } else if (m_timeCodeB[53]) { m_dst = RadioClockSettings::STARTING; } else { m_dst = RadioClockSettings::NOT_IN_EFFECT; } QString parityError; if (!oddParity(39, 51, m_timeCodeB[57])) { parityError = "Hour/minute parity error"; } if (!oddParity(25, 35, m_timeCodeB[55])) { parityError= "Day/month parity error"; } if (!oddParity(17, 24, m_timeCodeB[54])) { parityError = "Hour/minute parity error"; } if (parityError.isEmpty()) { // Bit 58B indicates BST rather than GMT m_dateTime = QDateTime(QDate(year, month, day), QTime(hour, minute), Qt::OffsetFromUTC, m_timeCodeB[58] ? 1*3600 : 0); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("OK")); } } else { m_dateTime = m_dateTime.addSecs(1); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create(parityError)); } } m_second = 0; } else { m_second++; m_dateTime = m_dateTime.addSecs(1); } if (getMessageQueueToChannel()) { RadioClock::MsgDateTime *msg = RadioClock::MsgDateTime::create(m_dateTime, m_dst); getMessageQueueToChannel()->push(msg); } } else if (m_periodCount == 1000) { m_periodCount = 0; } } m_prevData = m_data; } // USA WWVB 60kHz // https://en.wikipedia.org/wiki/WWVB void RadioClockSink::wwvb() { // WWVB reduces carrier by -17dB // 0.2s reduction is zero bit, 0.5s reduction is one bit // 0.8s reduction is a marker. Seven markers per minute (0, 9, 19, 29, 39, 49, and 59s) and for leap second m_threshold = m_thresholdMovingAverage.asDouble() * m_linearThreshold; // xdB below average m_data = m_magsq > m_threshold; // Look for minute marker - two consequtive markers if ((m_data == 0) && (m_prevData == 1)) { if ( (m_highCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.3) && (m_lowCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.7) ) { if (m_gotMarker && !m_gotMinuteMarker) { qDebug() << "RadioClockSink::wwvb - Minute marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount; m_gotMinuteMarker = true; m_second = 1; m_secondMarkers = 1; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Got minute marker")); } } else { qDebug() << "RadioClockSink::wwvb - Marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount << " second " << m_second; } m_gotMarker = true; m_periodCount = 0; } else { m_gotMarker = false; } m_lowCount = 0; } else if ((m_data == 1) && (m_prevData == 0)) { m_highCount = 0; } else if (m_data == 1) { m_highCount++; } else if (m_data == 0) { m_lowCount++; } m_sample = false; if (m_gotMinuteMarker) { m_periodCount++; if (m_periodCount == 100) { // Check we get second marker m_secondMarkers += m_data == 0; // If we see too many 1s instead of 0s, assume we've lost the signal if ((m_second > 10) && (m_secondMarkers / m_second < 0.7)) { qDebug() << "RadioClockSink::wwvb - Lost lock: " << m_secondMarkers << m_second; m_gotMinuteMarker = false; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } m_sample = true; } else if (m_periodCount == 350) { // Get data bit A for timecode m_timeCode[m_second] = !m_data; // No carrier = 1, carrier = 0 m_sample = true; } else if (m_periodCount == 950) { if (m_second == 59) { // Check markers are decoded as 1s const QList markerBits = {9, 19, 29, 39, 49, 59}; int missingMarkers = 0; for (int i = 0; i < markerBits.size(); i++) { if (m_timeCode[markerBits[i]] != 1) { missingMarkers++; qDebug() << "RadioClockSink::wwvb - Missing marker at bit " << markerBits[i]; } } if (missingMarkers >= 3) { m_gotMinuteMarker = false; qDebug() << "RadioClockSink::wwvb - Lost lock: Missing markers: " << missingMarkers; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } // Check 0s where expected const QList zeroBits = {4, 10, 11, 14, 20, 21, 24, 34, 35, 44, 54}; for (int i = 0; i < zeroBits.size(); i++) { if (m_timeCode[zeroBits[i]] != 0) { qDebug() << "RadioClockSink::wwvb - Unexpected 1 at bit " << zeroBits[i]; } } // Decode timecode to time and date int minute = bcdMSB(1, 8, 4); int hour = bcdMSB(12, 18, 14); int dayOfYear = bcdMSB(22, 33, 24, 29); int year = 2000 + bcdMSB(45, 53, 49); // Daylight savings int dst = (m_timeCode[57] << 1) | m_timeCode[58]; switch (dst) { case 0: m_dst = RadioClockSettings::NOT_IN_EFFECT; break; case 1: m_dst = RadioClockSettings::ENDING; break; case 2: m_dst = RadioClockSettings::STARTING; break; case 3: m_dst = RadioClockSettings::IN_EFFECT; break; } // Time is UTC QDate date(year, 1, 1); date = date.addDays(dayOfYear - 1); m_dateTime = QDateTime(date, QTime(hour, minute), Qt::OffsetFromUTC, 0); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("OK")); } m_second = 0; } else { m_second++; m_dateTime = m_dateTime.addSecs(1); } if (getMessageQueueToChannel()) { RadioClock::MsgDateTime *msg = RadioClock::MsgDateTime::create(m_dateTime, m_dst); getMessageQueueToChannel()->push(msg); } } else if (m_periodCount == 1000) { m_periodCount = 0; } } m_prevData = m_data; } // Japan JJY 40kHz // https://en.wikipedia.org/wiki/JJY void RadioClockSink::jjy() { // JJY reduces carrier by -10dB // Full power, then reduced power, which is the opposite of WWVB // 0.8s full power is is zero bit, 0.5s full power is one bit // 0.2s full power is a marker. Seven markers per minute (0, 9, 19, 29, 39, 49, and 59s) and for leap second m_threshold = m_thresholdMovingAverage.asDouble() * m_linearThreshold; // xdB below average m_data = m_magsq > m_threshold; // Look for minute marker - two consequtive markers if ((m_data == 1) && (m_prevData == 0)) { if ( (m_highCount <= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.3) && (m_lowCount >= RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE * 0.7) ) { if (m_gotMarker && !m_gotMinuteMarker) { qDebug() << "RadioClockSink::jjy - Minute marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount; m_gotMinuteMarker = true; m_second = 1; m_secondMarkers = 1; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Got minute marker")); } } else { qDebug() << "RadioClockSink::jjy - Marker: (low " << m_lowCount << " high " << m_highCount << ") prev period " << m_periodCount << " second " << m_second; } m_gotMarker = true; m_periodCount = 0; } else { m_gotMarker = false; } m_highCount = 0; } else if ((m_data == 0) && (m_prevData == 1)) { m_lowCount = 0; } else if (m_data == 1) { m_highCount++; } else if (m_data == 0) { m_lowCount++; } m_sample = false; if (m_gotMinuteMarker) { m_periodCount++; if (m_periodCount == 100) { // Check we get second marker m_secondMarkers += m_data == 1; // If we see too many 0s instead of 1s, assume we've lost the signal if ((m_second > 10) && (m_secondMarkers / m_second < 0.7)) { qDebug() << "RadioClockSink::jjy - Lost lock: " << m_secondMarkers << m_second; m_gotMinuteMarker = false; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } m_sample = true; } else if (m_periodCount == 650) { // Get data bit A for timecode m_timeCode[m_second] = !m_data; // No carrier = 1, carrier = 0 m_sample = true; } else if (m_periodCount == 950) { if (m_second == 59) { // Check markers are decoded as 1s const QList markerBits = {9, 19, 29, 39, 49, 59}; int missingMarkers = 0; for (int i = 0; i < markerBits.size(); i++) { if (m_timeCode[markerBits[i]] != 1) { missingMarkers++; qDebug() << "RadioClockSink::jjy - Missing marker at bit " << markerBits[i]; } } if (missingMarkers >= 3) { m_gotMinuteMarker = false; qDebug() << "RadioClockSink::jjy - Lost lock: Missing markers: " << missingMarkers; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } // Check 0s where expected const QList zeroBits = {4, 10, 11, 14, 20, 21, 24, 34, 35, 44, 55, 56, 57, 58}; for (int i = 0; i < zeroBits.size(); i++) { if (m_timeCode[zeroBits[i]] != 0) { qDebug() << "RadioClockSink::jjy - Unexpected 1 at bit " << zeroBits[i]; } } // Decode timecode to time and date int minute = bcdMSB(1, 8, 4); int hour = bcdMSB(12, 18, 14); int dayOfYear = bcdMSB(22, 33, 24, 29); int year = 2000 + bcdMSB(41, 48); // Japan doesn't have daylight savings m_dst = RadioClockSettings::NOT_IN_EFFECT; // Time is UTC QDate date(year, 1, 1); date = date.addDays(dayOfYear - 1); m_dateTime = QDateTime(date, QTime(hour, minute), Qt::OffsetFromUTC, 0); if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("OK")); } m_second = 0; } else { m_second++; m_dateTime = m_dateTime.addSecs(1); } if (getMessageQueueToChannel()) { RadioClock::MsgDateTime *msg = RadioClock::MsgDateTime::create(m_dateTime, m_dst); getMessageQueueToChannel()->push(msg); } } else if (m_periodCount == 1000) { m_periodCount = 0; } } m_prevData = m_data; } void RadioClockSink::processOneSample(Complex &ci) { // Calculate average and peak levels for level meter Real re = ci.real() / SDR_RX_SCALEF; Real im = ci.imag() / SDR_RX_SCALEF; Real magsq = re*re + im*im; m_movingAverage(magsq); m_thresholdMovingAverage(magsq); m_magsq = m_movingAverage.asDouble(); m_magsqSum += magsq; if (magsq > m_magsqPeak) { m_magsqPeak = magsq; } m_magsqCount++; // Demodulate if (m_settings.m_modulation == RadioClockSettings::DCF77) { dcf77(); } else if (m_settings.m_modulation == RadioClockSettings::TDF) { tdf(ci); } else if (m_settings.m_modulation == RadioClockSettings::WWVB) { wwvb(); } else if (m_settings.m_modulation == RadioClockSettings::JJY) { jjy(); } else { msf60(); } // Feed signals to scope sampleToScope(Complex(re, im)); } void RadioClockSink::applyChannelSettings(int channelSampleRate, int channelFrequencyOffset, bool force) { qDebug() << "RadioClockSink::applyChannelSettings:" << " channelSampleRate: " << channelSampleRate << " channelFrequencyOffset: " << channelFrequencyOffset; if ((m_channelFrequencyOffset != channelFrequencyOffset) || (m_channelSampleRate != channelSampleRate) || force) { m_nco.setFreq(-channelFrequencyOffset, channelSampleRate); } if ((m_channelSampleRate != channelSampleRate) || force) { m_interpolator.create(16, channelSampleRate, m_settings.m_rfBandwidth / 2.2); m_interpolatorDistance = (Real) channelSampleRate / (Real) RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE; m_interpolatorDistanceRemain = m_interpolatorDistance; } m_channelSampleRate = channelSampleRate; m_channelFrequencyOffset = channelFrequencyOffset; } void RadioClockSink::applySettings(const RadioClockSettings& settings, bool force) { qDebug() << "RadioClockSink::applySettings:" << " m_rfBandwidth: " << settings.m_rfBandwidth << " m_threshold: " << settings.m_threshold << " m_modulation: " << settings.m_modulation << " force: " << force; if ((settings.m_rfBandwidth != m_settings.m_rfBandwidth) || force) { m_interpolator.create(16, m_channelSampleRate, settings.m_rfBandwidth / 2.2); m_interpolatorDistance = (Real) m_channelSampleRate / (Real) RadioClockSettings::RADIOCLOCK_CHANNEL_SAMPLE_RATE; m_interpolatorDistanceRemain = m_interpolatorDistance; } if ((settings.m_threshold != m_settings.m_threshold) || force) { m_linearThreshold = CalcDb::powerFromdB(-settings.m_threshold); } if ((settings.m_modulation != m_settings.m_modulation) || force) { m_gotMinuteMarker = false; m_lowCount = 0; m_highCount = 0; m_zeroCount = 0; m_second = 0; m_dst = RadioClockSettings::UNKNOWN; if (getMessageQueueToChannel()) { getMessageQueueToChannel()->push(RadioClock::MsgStatus::create("Looking for minute marker")); } } m_settings = settings; }