mirror of https://github.com/arendst/Tasmota.git
update xsns_60_GPS.ino
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17c605ac6a
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cefc278bdf
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@ -17,63 +17,81 @@
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bool NtpServer::beginListening()
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{
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if (timeServerPort_.begin(NTP_PORT)){
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return true;
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}
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return false;
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if (timeServerPort_.begin(NTP_PORT)){
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return true;
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}
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return false;
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}
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bool NtpServer::processOneRequest(uint32_t utc, uint32_t millisecs)
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{
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// We need the time we've received the packet in our response.
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uint32_t recvSecs = utc + NTP_TIMESTAMP_DIFF;
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double recvFractDouble = (double)millisecs/0.00023283064365386963; // millisec/((10^6)/(2^32))
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uint32_t recvFract = (double)recvFractDouble; //TODO: really handle this!!!
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bool processed = false;
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int packetDataSize = timeServerPort_.parsePacket();
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if (packetDataSize && packetDataSize >= NtpPacket::PACKET_SIZE)
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{
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// Received what is probably an NTP packet. Read it in and verify
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// that it's legit.
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NtpPacket packet;
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timeServerPort_.read((char*)&packet, NtpPacket::PACKET_SIZE);
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// TODO: verify packet.
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// millisecs is millis() at the time of the last iTOW reception, where iTOW%1000 == 0
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uint32_t refMillis = millis()-millisecs;
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if (refMillis>999){
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utc++;
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refMillis = refMillis%1000;
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}
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// Populate response.
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packet.swapEndian();
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packet.leapIndicator(0);
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packet.versionNumber(4);
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packet.mode(4);
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packet.stratum = 2; // I guess stratum 1 is too optimistic
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packet.poll = 10; // 6-10 per RFC 5905.
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packet.precision = -21; // ~0.5 microsecond precision.
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packet.rootDelay = 0; //60 * (0xFFFF / 1000); // ~60 milliseconds, TBD
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packet.rootDispersion = 0; //10 * (0xFFFF / 1000); // ~10 millisecond dispersion, TBD
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packet.referenceId[0] = 'G';
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packet.referenceId[1] = 'P';
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packet.referenceId[2] = 'S';
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packet.referenceId[3] = 0;
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packet.referenceTimestampSeconds = utc;
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packet.referenceTimestampFraction = recvFract;
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packet.originTimestampSeconds = packet.transmitTimestampSeconds;
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packet.originTimestampFraction = packet.transmitTimestampFraction;
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packet.receiveTimestampSeconds = recvSecs;
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packet.receiveTimestampFraction = recvFract;
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// ...and the transmit time.
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// timeSource_.now(&packet.transmitTimestampSeconds, &packet.transmitTimestampFraction);
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// Now transmit the response to the client.
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packet.swapEndian();
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timeServerPort_.beginPacket(timeServerPort_.remoteIP(), timeServerPort_.remotePort());
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for (int count = 0; count < NtpPacket::PACKET_SIZE; count++)
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{
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timeServerPort_.write(packet.packet()[count]);
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}
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timeServerPort_.endPacket();
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processed = true;
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}
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return processed;
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bool processed = false;
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int packetDataSize = timeServerPort_.parsePacket();
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if (packetDataSize && packetDataSize >= NtpPacket::PACKET_SIZE)
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{
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// We need the time we've received the packet in our response.
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uint32_t recvSecs = utc + NTP_TIMESTAMP_DIFF;
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uint64_t recvFract64 = refMillis;
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recvFract64 <<= 32;
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recvFract64 /= 1000;
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uint32_t recvFract = recvFract64 & 0xffffffff;
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// is equal to:
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// uint32_t recvFract = (double)(refMillis)/0.00000023283064365386963;
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// Received what is probably an NTP packet. Read it in and verify
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// that it's legit.
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NtpPacket packet;
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timeServerPort_.read((char*)&packet, NtpPacket::PACKET_SIZE);
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// TODO: verify packet.
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// Populate response.
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packet.swapEndian();
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packet.leapIndicator(0);
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packet.versionNumber(4);
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packet.mode(4);
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packet.stratum = 1; // >1 will lead to misinterpretation of refId
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packet.poll = 10; // 6-10 per RFC 5905.
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packet.precision = -21; // ~0.5 microsecond precision.
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packet.rootDelay = 100 * (0xFFFF / 1000); //~100 milliseconds
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packet.rootDispersion = 50 * (0xFFFF / 1000);; //~50 millisecond dispersion
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packet.referenceId[0] = 'G';
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packet.referenceId[1] = 'P';
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packet.referenceId[2] = 'S';
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packet.referenceId[3] = 0;
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packet.referenceTimestampSeconds = recvSecs;
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packet.referenceTimestampFraction = 0; // the "click" of the GPS
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packet.originTimestampSeconds = packet.transmitTimestampSeconds;
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packet.originTimestampFraction = packet.transmitTimestampFraction;
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packet.receiveTimestampSeconds = recvSecs;
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packet.receiveTimestampFraction = recvFract;
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// ...and the transmit time.
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// the latency has been between 135 and 175 microseconds in internal testing, so we harcode 150
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uint32_t transFract = recvFract+(150*(10^3)/(2^32)); // microsec/((10^3)/(2^32))
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if (recvFract>transFract){
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recvSecs++; //overflow
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}
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packet.transmitTimestampSeconds = recvSecs;
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packet.transmitTimestampFraction = transFract;
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// Now transmit the response to the client.
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packet.swapEndian();
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timeServerPort_.beginPacket(timeServerPort_.remoteIP(), timeServerPort_.remotePort());
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timeServerPort_.write(packet.packet(), NtpPacket::PACKET_SIZE);
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timeServerPort_.endPacket();
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processed = true;
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}
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return processed;
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}
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@ -129,6 +129,7 @@ const char kUBXTypes[] PROGMEM = "UBX";
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#define UBX_SERIAL_BUFFER_SIZE 256
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#define UBX_TCP_PORT 1234
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#define NTP_MILLIS_OFFSET 50 // estimated latency in milliseconds
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/********************************************************************************************\
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| *globals
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@ -251,7 +252,8 @@ struct UBX_t {
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uint32_t last_vAcc;
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uint8_t gpsFix;
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uint8_t non_empty_loops; // in case of an unintended reset of the GPS, the serial interface will get flooded with NMEA
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uint16_t log_interval; // in tenth of seconds
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uint16_t log_interval; // in tenth of seconds
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int32_t timeOffset; // roughly computed offset millis() - iTOW
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} state;
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struct {
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@ -260,6 +262,7 @@ struct UBX_t {
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uint32_t send_when_new:1; // no teleinterval
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uint32_t send_UI_only:1;
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uint32_t runningNTP:1;
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// uint32_t blockedNTP:1;
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uint32_t forceUTCupdate:1;
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uint32_t runningVPort:1;
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// TODO: more to come
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@ -322,6 +325,15 @@ void UBXinitCFG(void)
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DEBUG_SENSOR_LOG(PSTR("UBX: turn off NMEA"));
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}
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void UBXsendCFGLine(uint8_t _line)
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{
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if (_line>sizeof(UBLOX_INIT)/16) return;
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for (uint32_t i = 0; i < 16; i++) {
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UBXSerial->write( pgm_read_byte(UBLOX_INIT+i+(_line*16)) );
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}
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DEBUG_SENSOR_LOG(PSTR("UBX: send line %u of UBLOX_INIT"), _line);
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}
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void UBXTriggerTele(void)
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{
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mqtt_data[0] = '\0';
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@ -583,6 +595,8 @@ void UBXSelectMode(uint16_t mode)
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break;
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case 10:
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UBX.mode.runningNTP = false;
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UBXsendCFGLine(10); //NAV-POSLLH on
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UBXsendCFGLine(11); //NAV-STATUS on
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break;
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case 11:
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UBX.mode.forceUTCupdate = true;
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@ -604,7 +618,6 @@ void UBXSelectMode(uint16_t mode)
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break;
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default:
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if (mode>1000 && mode <1066) {
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// UBXSetRate(mode-1000); // min. 1001 = 0.001 Hz, but will be converted to 1/65535 anyway ~0.015 Hz, max. 2000 = 1.000 Hz
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UBXSetRate(mode-1000); // set interval between measurements in seconds from 1 to 65
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}
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break;
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@ -629,13 +642,16 @@ bool UBXHandlePOSLLH()
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UBX.rec_buffer.values.lon = UBX.Message.navPosllh.lon;
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DEBUG_SENSOR_LOG(PSTR("UBX: lat/lon: %i / %i"), UBX.rec_buffer.values.lat, UBX.rec_buffer.values.lon);
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DEBUG_SENSOR_LOG(PSTR("UBX: hAcc: %d"), UBX.Message.navPosllh.hAcc);
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UBX.state.last_iTOW = UBX.Message.navPosllh.iTOW;
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UBX.state.last_alt = UBX.Message.navPosllh.alt;
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UBX.state.last_vAcc = UBX.Message.navPosllh.vAcc;
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UBX.state.last_hAcc = UBX.Message.navPosllh.hAcc;
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if (UBX.mode.send_when_new) {
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UBXTriggerTele();
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}
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if (UBX.mode.runningNTP){ // after receiving pos-data at least once -> go to pure NTP-mode
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UBXsendCFGLine(7); //NAV-POSLLH off
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UBXsendCFGLine(8); //NAV-STATUS off
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}
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return true; // new position
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} else {
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DEBUG_SENSOR_LOG(PSTR("UBX: no valid position data"));
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@ -657,9 +673,9 @@ void UBXHandleTIME()
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{
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DEBUG_SENSOR_LOG(PSTR("UBX: UTC-Time: %u-%u-%u %u:%u:%u"), UBX.Message.navTime.year, UBX.Message.navTime.month ,UBX.Message.navTime.day,UBX.Message.navTime.hour,UBX.Message.navTime.min,UBX.Message.navTime.sec);
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if (UBX.Message.navTime.valid.UTC == 1) {
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UBX.state.timeOffset = millis(); // iTOW%1000 should be 0 here, when NTP-server is enabled and in "pure mode"
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DEBUG_SENSOR_LOG(PSTR("UBX: UTC-Time is valid"));
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if (Rtc.user_time_entry == false || UBX.mode.forceUTCupdate) {
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AddLog_P(LOG_LEVEL_INFO, PSTR("UBX: UTC-Time is valid, set system time"));
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if (Rtc.user_time_entry == false || UBX.mode.forceUTCupdate || UBX.mode.runningNTP) {
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TIME_T gpsTime;
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gpsTime.year = UBX.Message.navTime.year - 1970;
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gpsTime.month = UBX.Message.navTime.month;
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@ -667,7 +683,11 @@ void UBXHandleTIME()
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gpsTime.hour = UBX.Message.navTime.hour;
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gpsTime.minute = UBX.Message.navTime.min;
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gpsTime.second = UBX.Message.navTime.sec;
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Rtc.utc_time = MakeTime(gpsTime);
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UBX.rec_buffer.values.time = MakeTime(gpsTime);
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if (UBX.mode.forceUTCupdate || Rtc.user_time_entry == false){
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AddLog_P(LOG_LEVEL_INFO, PSTR("UBX: UTC-Time is valid, set system time"));
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Rtc.utc_time = UBX.rec_buffer.values.time;
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}
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Rtc.user_time_entry = true;
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}
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}
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@ -705,7 +725,7 @@ void UBXLoop50msec(void)
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}
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// handle NTP-server
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if(UBX.mode.runningNTP){
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timeServer.processOneRequest(Rtc.utc_time, UBX.state.last_iTOW%1000);
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timeServer.processOneRequest(UBX.rec_buffer.values.time, UBX.state.timeOffset - NTP_MILLIS_OFFSET);
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}
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}
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