some changes

with fixed ADC code
only format code
2022-05-21 17:40:50 +02:00 · 2020-08-04 16:19:15 +02:00 · 2020-08-04 16:16:30 +02:00 · 2020-07-21 14:27:58 +02:00 · 2020-07-21 10:33:14 +02:00 · 2020-07-14 19:45:25 +02:00
4 changed files with 272 additions and 378 deletions
--- a/README.md
+++ b/README.md
@ -20,9 +20,9 @@ Das sind die verwendeten Libraries [1]:
 | --- | -----  | ----------- |
 | https://github.com/mcci-catena/Adafruit_BME280_Library.git  | 3dafbe1 | Wed, 13 Dec 2017 13:56:30 -0500  |
 | https://github.com/mcci-catena/Adafruit_Sensor.git  | f2af6f4 | Tue, 1 Sep 2015 15:57:59 +0200  |
-| https://github.com/mcci-catena/arduino-lmic.git  | 6fe04ec | Tue, 12 May 2020 09:16:47 -0400  |
+| https://github.com/mcci-catena/arduino-lmic.git  | 9191f0c | Tue, 30 Jun 2020 09:56:19 -0400  |
 | https://github.com/mcci-catena/arduino-lorawan.git  | 4bc0d48 | Sat, 9 May 2020 12:38:28 -0400  |
-| https://github.com/mcci-catena/Catena-Arduino-Platform.git  | 92019ca | Tue, 12 May 2020 01:34:08 -0400  |
+| https://github.com/mcci-catena/Catena-Arduino-Platform.git  | 7620a89 | Fri, 31 Jul 2020 14:14:30 -0400  |
 | https://github.com/mcci-catena/Catena-mcciadk.git  | a428006 | Sat, 21 Dec 2019 20:45:26 -0500  |
 | https://github.com/mcci-catena/MCCI_FRAM_I2C.git  | f0a5ea5 | Sat, 21 Dec 2019 16:17:01 -0500  |
 | https://github.com/tatobari/Q2-HX711-Arduino-Library.git  | ccda8d8 | Wed, 13 Mar 2019 12:41:44 -0300  |
@ -31,5 +31,45 @@ Das sind die verwendeten Libraries [1]:
 | https://github.com/mcci-catena/SHT1x.git  | be7042c | Tue, 20 Sep 2011 13:56:23 +1000  |
 Patch arduino-lmic, so initial SF12 is used initially:
 `
 [joerg@cinnamon src]$ git diff
 diff --git a/src/lmic/lmic_bandplan_eu868.h b/src/lmic/lmic_bandplan_eu868.h
 index efff7d5..74efb37 100644
 --- a/src/lmic/lmic_bandplan_eu868.h
 +++ b/src/lmic/lmic_bandplan_eu868.h
@@ -61,7 +61,7 @@ LMICeu868_isValidBeacon1(const uint8_t *d) {
 #undef LMICbandplan_isFSK
 #define LMICbandplan_isFSK()    (/* RX datarate */LMIC.dndr == EU868_DR_FSK)
 -#define LMICbandplan_getInitialDrJoin() (EU868_DR_SF7)
 +#define LMICbandplan_getInitialDrJoin() (EU868_DR_SF12)
 void LMICeu868_setBcnRxParams(void);
 #define LMICbandplan_setBcnRxParams()   LMICeu868_setBcnRxParams()
 `
 `[1]:
 [joerg@cinnamon libraries]$ for i in Adafruit_BME280_Library Adafruit_Sensor arduino-lmic arduino-lorawan Catena-Arduino-Platform Catena-mcciadk MCCI_FRAM_I2C Q2-HX711-Arduino-Library SparkFun_Qwiic_Scale_NAU7802_Arduino_Library OneWire SHT1x ; do cd $i; echo "| $(git remote -v |grep fetch |awk '{print $2}' |tr '\n' ' ') | $(git log --pretty=format:'%h | %cD ' -n 1) |" ; cd ..; done`
 ## Some Facts about RSSI and SNR
 https://lora.readthedocs.io/en/latest/#rssi
 RSSI minimum = -120 dBm.
 RSSI < -90 dBm: this signal is extremely weak, at the edge of what a receiver can receive.
 RSSI -67dBm: this is a fairly strong signal.
 RSSI > -55dBm: this is a very strong signal.
 RSSI > -30dBm: your sniffer is sitting right next to the transmitter.
 https://lora.readthedocs.io/en/latest/#snr
 Typical LoRa SNR values are between: -20dB and +10dB
 A value closer to +10dB means the received signal is less corrupted.
 LoRa can demodulate signals which are -7.5 dB to -20 dB below the noise floor.
--- a/mini-beieli-node.ino
+++ b/mini-beieli-node.ino
@ -60,6 +60,7 @@ cCommandStream::CommandFn cmdGetScaleA;
 cCommandStream::CommandFn cmdGetScaleB;
 cCommandStream::CommandFn cmdCalibrateZeroScaleA;
 cCommandStream::CommandFn cmdCalibrateZeroScaleB;
 cCommandStream::CommandFn cmdCalibrateScales;
 cCommandStream::CommandFn cmdCalibrateScaleA;
 cCommandStream::CommandFn cmdCalibrateScaleB;
 cCommandStream::CommandFn cmdSetDebugLevel;
@ -72,6 +73,7 @@ static const cCommandStream::cEntry sMyExtraCommmands[] =
  { "hello", cmdHello },
  { "get_calibration_settings", cmdGetCalibrationSettings },
  { "get_sensor_readings", cmdGetSensorReadings },
  { "calibrate_scales", cmdCalibrateScales },
  { "calibrate_zero_scale_a", cmdCalibrateZeroScaleA },
  { "calibrate_zero_scale_b", cmdCalibrateZeroScaleB },
  { "calibrate_scale_a", cmdCalibrateScaleA },
@ -99,7 +101,7 @@ sMyExtraCommands_top(
  \****************************************************************************/
 byte my_position = 0;    // what is our actual measurement, starts with 0
-long timer_pos0;
+unsigned long timer_pos0;
 // Global Variables
 LORA_data lora_data;
@ -110,6 +112,7 @@ long iteration = 0;       // what iteration number do we have, starts with 0
 long package_counter = 0; // sent package counter
 bool send_in_progress = false;
 bool stop_iterations = false;
 bool start_new_iteration = false;
 bool next_package_is_init_package = true;
 uint32_t gRebootMs;
@ -143,24 +146,17 @@ bool fFlash;
 bool fUsbPower;
 // have we printed the sleep info?
 bool g_fPrintedSleeping = false;
 //  the job that's used to synchronize us with the LMIC code
 static osjob_t iterationJob;
 static osjob_t sendJob;
 // the cycle time to use
 unsigned gTxCycle;
 // remaining before we reset to default
 unsigned gTxCycleCount;
 void setup(void)
 {
  gCatena.begin();
  setup_platform();
  SetupScales(config_data.debug_level);
-  ClearLoraData();
+  ClearLoraData(true);
  setup_bme280();
  setup_flash();
@ -253,7 +249,6 @@ void setup_platform(void)
  }
  gLoRaWAN.SetReceiveBufferBufferCb(receiveMessage);
  setTxCycleTime(CATCFG_T_CYCLE_INITIAL, CATCFG_INTERVAL_COUNT_INITIAL);
  gCatena.registerObject(&gLoRaWAN);
  /* find the platform */
@ -348,6 +343,9 @@ void setup_uplink(void)
  LMIC_setClockError(1 * 65536 / 100);
  // explicitly enable LinkCheckMode
  gLoRaWAN.SetLinkCheckMode(true);
  /* figure out when to reboot */
  gRebootMs = (CATCFG_T_REBOOT + os_getRndU2() - 32768) * 1000;
@ -379,9 +377,12 @@ void setup_uplink(void)
 void loop()
 {
  gCatena.poll();
  if (start_new_iteration) {
    StartNewIteration();
  }
 }
-void ClearLoraData(void)
+void ClearLoraData(bool clearLastValues)
 {
  lora_data.version = LORA_DATA_VERSION;
  lora_data.vbat = 0;
@ -411,13 +412,15 @@ void ClearLoraData(void)
  my_position = 0;
  // We initialize last_sensor_reading
-  last_sensor_reading.vbat = 0;
+  if (clearLastValues) {
-  last_sensor_reading.weight1 = 0;
+    last_sensor_reading.vbat = 0;
-  last_sensor_reading.weight2 = 0;
+    last_sensor_reading.weight1 = 0;
-  last_sensor_reading.weight = 0;
+    last_sensor_reading.weight2 = 0;
-  last_sensor_reading.temperature = 0;
+    last_sensor_reading.weight = 0;
-  last_sensor_reading.humidity = 0;
+    last_sensor_reading.temperature = 0;
-  last_sensor_reading.pressure = 0;
+    last_sensor_reading.humidity = 0;
    last_sensor_reading.pressure = 0;
  }
 }
 void ShowLORAData(bool firstTime)
@ -503,7 +506,7 @@ uint8_t GetVBatValue(int millivolts)
 void DoDeepSleep(uint32_t sleep_time)
 {
  if (config_data.debug_level > 0) {
-    gCatena.SafePrintf("DoDeepSleep, now going to deep sleep\n");
+    gCatena.SafePrintf("DoDeepSleep, now going to deep sleep, millis: %d\n", millis());
  }
  // Prepare Deep Sleep
@ -520,13 +523,19 @@ void DoDeepSleep(uint32_t sleep_time)
  deepSleepRecovery();
  if (config_data.debug_level > 0) {
-    gCatena.SafePrintf("done with deep sleep\n");
+    gCatena.SafePrintf("done with deep sleep, millis: %d\n", millis());
  }
 }
-void ReadSensors(SENSOR_data &sensor_data) {
+// Returns true if measurements are plausible, otherwise false
 bool ReadSensors(SENSOR_data &sensor_data) {
  bool plausible;
  bool plausible_a;
  bool plausible_b;
  SENSOR_data res;
  int32_t weight_current32;
  int32_t weight_current32_a;
  int32_t weight_current32_b;
  long w1_0_real;
  long w2_0_real;
@ -544,29 +553,13 @@ void ReadSensors(SENSOR_data &sensor_data) {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("LoadCell is ready.\n");
    }
-    if (config_data.cal_w1_0 != NOT_ATTACHED) {
+    res.weight1 = (int32_t)ReadScale('A');
-      res.weight1 = (int32_t)ReadScale('A');
+    if (config_data.debug_level > 0) {
-      if (config_data.debug_level > 0) {
+      gCatena.SafePrintf("Load_cell 1 weight1_current: %ld\n", res.weight1);
        gCatena.SafePrintf("Load_cell 1 weight1_current: %ld\n", res.weight1);
      }
    } else {
      res.weight1 = 0;
      w1_0_real = 0;
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("Load_cell 1 is disabled\n");
      }
    }
-    if (config_data.cal_w2_0 != NOT_ATTACHED) {
+    res.weight2 = (int32_t)ReadScale('B');
-      res.weight2 = (int32_t)ReadScale('B');
+    if (config_data.debug_level > 0) {
-      if (config_data.debug_level > 0) {
+      gCatena.SafePrintf("Load_cell 2 weight2_current: %ld\n", res.weight2);
        gCatena.SafePrintf("Load_cell 2 weight2_current: %ld\n", res.weight2);
      }
    } else {
      res.weight2 = 0;
      w2_0_real = 0;
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("Load_cell 2 is disabled\n");
      }
    }
  }
  else {
@ -579,18 +572,32 @@ void ReadSensors(SENSOR_data &sensor_data) {
  PowerdownScale();
  // Gewicht berechnen
-  weight_current32 = (int32_t)((((res.weight1 - w1_0_real) / config_data.cal_w1_factor) + ((res.weight2 - w2_0_real) / config_data.cal_w2_factor)) / 5.0);
+  weight_current32_a = (int32_t)((res.weight1 - w1_0_real) / config_data.cal_w1_factor);
  weight_current32_b = (int32_t)((res.weight2 - w2_0_real) / config_data.cal_w2_factor);
  weight_current32 = (int32_t)((weight_current32_a + weight_current32_b) / 5.0);
  // we check if weights are plausible
  plausible_a = (weight_current32_a > -10000) && (weight_current32_a < 150000);
  plausible_b = (weight_current32_b > -10000) && (weight_current32_b < 150000);
  plausible = (plausible_a && plausible_b);
  if (weight_current32 < 0) {
-    weight_current32 = 0;
+    if (plausible) { 
      weight_current32 = 0;
    } 
  } else if (weight_current32 > UINT16_MAX) {
    //weight_current32 = UINT16_MAX;
    // we set the weight to 0, as such high values are not realistic and probably a sign for bad calibration...
    weight_current32 = 0;
  }
-  if (config_data.cal_w1_0 == NOT_ATTACHED || config_data.cal_w2_0 == NOT_ATTACHED) {
+  if (!plausible) {
-    // when at least one load cell is disabled, we multiply the measured weight by 2
+    weight_current32 = NOT_PLAUSIBLE_16;
-    weight_current32 = weight_current32 * 2;
+    if (!plausible_a) {
      res.weight1 = NOT_PLAUSIBLE_32;
    }
    if (!plausible_b) {
      res.weight2 = NOT_PLAUSIBLE_32;
    }
  }
  res.weight = (uint16_t)weight_current32;
@ -618,9 +625,11 @@ void ReadSensors(SENSOR_data &sensor_data) {
  }
  sensor_data = res;
  return plausible;
 }
 void StartNewIteration() {
  start_new_iteration = false;
  uint32_t wait_time;
  wait_time = 0;
@ -628,7 +637,18 @@ void StartNewIteration() {
  iteration++;
  SENSOR_data current_sensor_reading;
-  ReadSensors(current_sensor_reading);
+  if (!ReadSensors(current_sensor_reading)) {
    // we try a second time if Readings do not seem plausible
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("Readings do not seem plausible, try a second time\n");
    }
    delay(500);
    if (!ReadSensors(current_sensor_reading)) {
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("Readings do not seem plausible for a second time, we give up!\n");
      }
    }
  }
  int16_t temp_change;
  // vBus
@ -677,35 +697,45 @@ void StartNewIteration() {
  // we send data the first time the system is started, when the array is full
  // or when the weight has fallen more than threshold or the first measurement is
  // more than one hour old (which should not happen :-) )
-  if ( (next_package_is_init_package) || (my_position >= MAX_VALUES_TO_SEND) || (abs(last_sensor_reading.weight - current_sensor_reading.weight) > SEND_DIFF_THRESHOLD_5GRAMS) || ((millis() - timer_pos0) > 3600000)) {
+  bool big_difference = (abs(last_sensor_reading.weight - current_sensor_reading.weight) > SEND_DIFF_THRESHOLD_5GRAMS);
  if ( (next_package_is_init_package) || (my_position >= MAX_VALUES_TO_SEND) || (big_difference) || ((millis() - timer_pos0) > 3600000)) {
    lora_data.offset_last_reading = (uint8_t)((millis() - timer_pos0) / 1000 / 60);
    if (config_data.debug_level > 0) {
-      gCatena.SafePrintf("startSendingUplink(), my_position: %d, iteration: %d, package_counter: %d\n", my_position, iteration, package_counter);
+      gCatena.SafePrintf("startSendingUplink(), my_position: %d, iteration: %d, package_counter: %d, big_difference: %d\n", my_position, iteration, package_counter, big_difference);
    }
    // the first <INIT_PACKETS> packets are "Init-Packets" or each INIT_PACKAGE_INTERVAL ...
-    startSendingUplink(next_package_is_init_package);
+    // send confirmed if big_difference in weight
    startSendingUplink(next_package_is_init_package, big_difference);
    next_package_is_init_package = ((iteration < INIT_PACKETS) || ((package_counter % INIT_PACKAGE_INTERVAL) == 0));
    if (config_data.debug_level > 1) {
      gLed.Set(LedPattern::TwoShort);
    }
-    // Loop while sending is in progress, timeout just in case after 300 seconds
+    // Loop sending is in progress, timeout just in case after 600 seconds
-    long start_time = millis();
+    unsigned long start_time = millis();
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("waiting while send is in progress\n");
    }
-    while (send_in_progress && ((millis() - start_time) < 300000))
+    while (send_in_progress && ((millis() - start_time) < 600000))
    {
-      os_runloop_once();
+      gCatena.poll();
-//      gCatena.poll();
+      yield();
 //      yield();
    }
    // handle timeout...
    if (send_in_progress) {
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("looks like we timed out waiting for sending to finish...\n", wait_time);
      }
      LMIC_clrTxData();
      // we sleep 10 seconds...
      start_time = millis();
      while ((millis() - start_time) < 10000)
      {
        gCatena.poll();
        yield();
      }
      send_in_progress = false;
    }
    wait_time = (uint32_t)((millis() - start_time) / 1000);
@ -717,6 +747,9 @@ void StartNewIteration() {
  if (not(next_package_is_init_package)) {
    // we make the current sensor reading to the last one...
    last_sensor_reading = current_sensor_reading;
  } else {
    // we only copy the last weight
    last_sensor_reading.weight = current_sensor_reading.weight;
  }
  uint32_t sleep_time_sec;
@ -727,9 +760,9 @@ void StartNewIteration() {
    sleep_time_sec = 5;
  }
-  // for the first <INIT_PACKETS> iterations, we set the sleep time to 10 seconds only...
+  // for the first <INIT_PACKETS> iterations, we set the sleep time to 120 seconds only...
  if (iteration <= INIT_PACKETS) {
-    sleep_time_sec = 10;
+    sleep_time_sec = 120;
  }
  if (config_data.debug_level > 0) {
@ -745,29 +778,43 @@ void StartNewIteration() {
    }
  }
-  if (!fUsbPower) {
+  // if we need to periodically reboot, we can do it now...
  if (uint32_t(millis()) > gRebootMs) {
    // time to reboot
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("Reached threshold to reboot...\n");
      Serial.flush();
    }
    NVIC_SystemReset();
  }
  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("LMIC.opmode just before Sleeping: %#x\n", LMIC.opmode);
    gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
    gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
  }
  if (!fUsbPower && !stop_iterations)  {
    DoDeepSleep(sleep_time_sec);
    if (! stop_iterations) {
-      StartNewIteration();
+      start_new_iteration = true;
    }
    //os_setTimedCallback(
    //  &iterationJob,
    //  os_getTime() + sec2osticks(2),
    //  startNewIterationCb);
  }
  else {
-    if (config_data.debug_level > 0) {
+    if (! stop_iterations) {
-      gCatena.SafePrintf("light sleep; os_setTimedCallback for startNewIterationCb in %d...seconds\n", sleep_time_sec);
+      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("light sleep; os_setTimedCallback for startNewIterationCb in %d...seconds\n", sleep_time_sec);
      }
      os_setTimedCallback(
        &iterationJob,
        os_getTime() + sec2osticks(sleep_time_sec),
        startNewIterationCb);
    }
    os_setTimedCallback(
      &iterationJob,
      os_getTime() + sec2osticks(sleep_time_sec),
      startNewIterationCb);
  }
 }
-void startSendingUplink(bool firstTime)
+void startSendingUplink(bool firstTime, bool confirmed)
 {
  send_in_progress = true;
@ -791,24 +838,50 @@ void startSendingUplink(bool firstTime)
    fConfirmed = true;
  }
-  os_runloop_once();
+  // we can overwrite fConfirmed
-  //gCatena.poll();
+  if (confirmed) {
    fConfirmed = true;
  }
  if (firstTime) {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("SendBuffer firstTime\n");
    }
-    gLoRaWAN.SendBuffer((uint8_t*)&lora_data_first, sizeof(LORA_data_first), sendBufferDoneCb, NULL, fConfirmed, kUplinkPort);
+    if (gLoRaWAN.SendBuffer((uint8_t*)&lora_data_first, sizeof(LORA_data_first), sendBufferDoneCb, NULL, fConfirmed, kUplinkPort)) {
-    package_counter++;
+      package_counter++;
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("LMIC.opmode just after SendBuffer (successful): %#x\n", LMIC.opmode);
        gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
        gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
      }
    }
    else {
      gCatena.SafePrintf("LMIC.opmode just before SendBuffer (failed): %#x\n", LMIC.opmode);
      gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
      gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
    }
  } else {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("LMIC.opmode just before SendBuffer: %#x\n", LMIC.opmode);
      gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
      gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
      gCatena.SafePrintf("SendBuffer not firstTime\n");
    }
-    gLoRaWAN.SendBuffer((uint8_t*)&lora_data, sizeof(LORA_data), sendBufferDoneCb, NULL, fConfirmed, kUplinkPort);
+    if (gLoRaWAN.SendBuffer((uint8_t*)&lora_data, sizeof(LORA_data), sendBufferDoneCb, NULL, fConfirmed, kUplinkPort)) {
-    package_counter++;
+      package_counter++;
      if (config_data.debug_level > 0) {
        gCatena.SafePrintf("LMIC.opmode just after SendBuffer (successful): %#x\n", LMIC.opmode);
        gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
        gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
      }
    } else {
      gCatena.SafePrintf("LMIC.opmode just before SendBuffer (failed): %#x\n", LMIC.opmode);
      gCatena.SafePrintf("LMIC.globalDutyRate: %d, LMIC.globalDutyAvail: %d, os_getTime: %d\n", LMIC.globalDutyRate, LMIC.globalDutyAvail, os_getTime());
      gCatena.SafePrintf("LMIC.seqnoUp: %d, LMIC.seqnoDn: %d\n", LMIC.seqnoUp, LMIC.seqnoDn);
    }
  }
-  ClearLoraData();
+  ClearLoraData(false);
 }
 static void sendBufferDoneCb(
@ -819,12 +892,12 @@ static void sendBufferDoneCb(
  if (config_data.debug_level > 1) {
    gLed.Set(LedPattern::Settling);
    gCatena.SafePrintf("LMIC.opmode in sendBufferDoneCb: %#x\n", LMIC.opmode);
  }
  pFn = settleDoneCb;
  if (! fStatus)
  {
    send_in_progress = false;
    if (!gLoRaWAN.IsProvisioned())
    {
      // we'll talk about it at the callback.
@ -834,7 +907,7 @@ static void sendBufferDoneCb(
      gLoRaWAN.Shutdown();
    }
    else if (config_data.debug_level > 0) {
-      gCatena.SafePrintf("send buffer failed\n");
+      gCatena.SafePrintf("send buffer failed, LMIC.opmode: %#x\n", LMIC.opmode);
    }
  }
@ -858,180 +931,56 @@ static void txNotProvisionedCb(
  }
 }
 static void settleDoneCb(
  osjob_t* pSendJob)
 {
  const bool fDeepSleep = checkDeepSleep();
  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("settleDoneCb\n");
  }
  if (config_data.debug_level > 2) {
    // Terry vv
    gCatena.SafePrintf("LMIC.rxDelay: %i\n", LMIC.rxDelay);
    gCatena.SafePrintf("LMIC.dn2Dr: %i\n", LMIC.dn2Dr);
    gCatena.SafePrintf("LMIC.dn2Freq: %i\n", LMIC.dn2Freq);
    gCatena.SafePrintf("LMIC.rx1DrOffset: %i\n", LMIC.rx1DrOffset);
    gCatena.SafePrintf("LMIC.adrAckReq: %i\n", LMIC.adrAckReq);
    gCatena.SafePrintf("LMIC.adrEnabled: %i\n", LMIC.adrEnabled);
    // Terry ^^
  }
  if (uint32_t(millis()) > gRebootMs) {
    // time to reboot
    NVIC_SystemReset();
  }
  if (! g_fPrintedSleeping)
    doSleepAlert(fDeepSleep);
  /* count what we're up to */
  updateSleepCounters();
  if (fDeepSleep)
    doDeepSleep(pSendJob);
  else
    doLightSleep(pSendJob);
 }
 bool checkDeepSleep(void)
 {
-  bool const fDeepSleepTest = gCatena.GetOperatingFlags() &
+  return !fUsbPower;
                              static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fDeepSleepTest);
  bool fDeepSleep;
  if (fDeepSleepTest)
  {
    fDeepSleep = true;
  }
 #ifdef USBCON
  else if (Serial.dtr())
  {
    fDeepSleep = false;
  }
 #endif
  else if (gCatena.GetOperatingFlags() &
           static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fDisableDeepSleep))
  {
    fDeepSleep = false;
  }
  else if ((gCatena.GetOperatingFlags() &
            static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fUnattended)) != 0)
  {
    fDeepSleep = true;
  }
  else
  {
    fDeepSleep = false;
  }
  return fDeepSleep;
 }
 void doSleepAlert(const bool fDeepSleep)
 {
-  g_fPrintedSleeping = true;
+  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("We wait until is is safe to go to sleep...\n");
  }
-  if (fDeepSleep)
+  for (int i = 0; i <= 15; i++) {
-  {
+    unsigned long prevPrint = millis();
-    bool const fDeepSleepTest = gCatena.GetOperatingFlags() &
+    while (os_queryTimeCriticalJobs(ms2osticks(2000)) != 0)
                                static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fDeepSleepTest);
    const uint32_t deepSleepDelay = fDeepSleepTest ? 10 : 30;
    if (config_data.debug_level > 2) {
      gCatena.SafePrintf("using deep sleep in %u secs"
 #ifdef USBCON
                         " (USB will disconnect while asleep)"
 #endif
                         ": ",
                         deepSleepDelay
                        );
    }
    // sleep and print
    if (config_data.debug_level > 1) {
      gLed.Set(LedPattern::TwoShort);
    }
    for (auto n = deepSleepDelay; n > 0; --n)
    {
-      uint32_t tNow = millis();
+      gCatena.poll();
-
+      yield();
-      while (uint32_t(millis() - tNow) < 1000)
+      if (millis() - prevPrint > 1000) {
-      {
+        prevPrint = millis();
-        os_runloop_once();
+        if (config_data.debug_level > 0) {
-        //gCatena.poll();
+          gCatena.SafePrintf("LMIC.opmode: %#x in loop %d\n", LMIC.opmode, i);
-        //yield();
+        }
      }
      if (config_data.debug_level > 2) {
        gCatena.SafePrintf(".");
      }
    }
    if (config_data.debug_level > 2) {
      gCatena.SafePrintf("\nStarting deep sleep.\n");
    }
    uint32_t tNow = millis();
    while (uint32_t(millis() - tNow) < 100)
    {
      os_runloop_once();
      //gCatena.poll();
      //yield();
    }
  }
  else if (config_data.debug_level > 2) {
    gCatena.SafePrintf("using light sleep\n");
  }
 }
 void updateSleepCounters(void)
 {
  // update the sleep parameters
  if (gTxCycleCount > 1)
  {
    // values greater than one are decremented and ultimately reset to default.
    --gTxCycleCount;
  }
  else if (gTxCycleCount == 1)
  {
    // it's now one (otherwise we couldn't be here.)
    if (config_data.debug_level > 2) {
      gCatena.SafePrintf("resetting tx cycle to default: %u\n", CATCFG_T_CYCLE);
    }
    gTxCycleCount = 0;
    gTxCycle = CATCFG_T_CYCLE;
  }
  else
  {
    // it's zero. Leave it alone.
  }
 }
 void doDeepSleep(osjob_t *pJob)
 {
  bool const fDeepSleepTest = gCatena.GetOperatingFlags() &
                              static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fDeepSleepTest);
  uint32_t const sleepInterval = CATCFG_GetInterval(
                                   fDeepSleepTest ? CATCFG_T_CYCLE_TEST : gTxCycle
                                 );
  if (config_data.debug_level > 0) {
-    gCatena.SafePrintf("doDeepSleep, sleepInterval: %d...\n", sleepInterval);
+    gCatena.SafePrintf("Now it is safe to go to sleep\n");
  }
-  /* ok... now it's time for a deep sleep */
+}
  gLed.Set(LedPattern::Off);
  deepSleepPrepare();
-  /* sleep */
+static void settleDoneCb(
-  gCatena.Sleep(sleepInterval);
+  osjob_t* pSendJob)
 {
  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("settleDoneCb - we are at the end of the callback chain!\n");
  }
-  /* recover from sleep */
+  const bool fDeepSleep = checkDeepSleep();
  deepSleepRecovery();
-  /* and now... we're awake again. trigger another measurement */
+  if (uint32_t(millis()) > gRebootMs)
-  sleepDoneCb(pJob);
+  {
    // time to reboot
    NVIC_SystemReset();
  }
  doSleepAlert(fDeepSleep);
  send_in_progress = false;
 }
 void deepSleepPrepare(void)
@ -1053,53 +1002,6 @@ void deepSleepRecovery(void)
    gSPI2.begin();
 }
 void doLightSleep(osjob_t *pJob)
 {
  uint32_t interval = sec2osticks(CATCFG_GetInterval(gTxCycle));
  if (config_data.debug_level > 1) {
    gLed.Set(LedPattern::Sleeping);
    gCatena.SafePrintf("doLightSleep\n");
  }
  if (gCatena.GetOperatingFlags() &
      static_cast<uint32_t>(gCatena.OPERATING_FLAGS::fQuickLightSleep))
  {
    interval = 1;
  }
  os_setTimedCallback(
    &iterationJob,
    os_getTime() + interval,
    sleepDoneCb
  );
 }
 static void sleepDoneCb(osjob_t* pJob)
 {
  if (config_data.debug_level > 1) {
    gLed.Set(LedPattern::WarmingUp);
  }
  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("sleepDoneCb\n");
  }
  os_setTimedCallback(
    pJob,
    os_getTime() + sec2osticks(CATCFG_T_WARMUP),
    warmupDoneCb);
 }
 static void warmupDoneCb(osjob_t* pJob)
 {
  if (config_data.debug_level > 0) {
    gCatena.SafePrintf("warmupDoneCb\n");
  }
  send_in_progress = false;
 }
 static void startNewIterationCb(osjob_t* pJob)
 {
@ -1108,14 +1010,12 @@ static void startNewIterationCb(osjob_t* pJob)
  }
  if (! stop_iterations) {
-    StartNewIteration();
+    start_new_iteration = true;
  }
 }
 static void receiveMessage(void *pContext, uint8_t port, const uint8_t *pMessage, size_t nMessage)
 {
  unsigned txCycle;
  unsigned txCount;
  long cal_w1_0;
  long cal_w2_0;
@ -1231,59 +1131,8 @@ static void receiveMessage(void *pContext, uint8_t port, const uint8_t *pMessage
    }
  }
  if (port == 0)
  {
    return;
  }
  else if (! (port == 1 && 2 <= nMessage && nMessage <= 3))
  {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("invalid message port(%02x)/length(%x)\n",
                         port, nMessage
                        );
    }
    return;
  }
  txCycle = (pMessage[0] << 8) | pMessage[1];
  if (txCycle < CATCFG_T_MIN || txCycle > CATCFG_T_MAX)
  {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("tx cycle time out of range: %u\n", txCycle);
    }
    return;
  }
  // byte [2], if present, is the repeat count.
  // explicitly sending zero causes it to stick.
  txCount = CATCFG_INTERVAL_COUNT;
  if (nMessage >= 3)
  {
    txCount = pMessage[2];
  }
  setTxCycleTime(txCycle, txCount);
 }
 void setTxCycleTime(unsigned txCycle, unsigned txCount)
 {
  if (txCount > 0) {
    if (config_data.debug_level > 0) {
      gCatena.SafePrintf("message cycle time %u seconds for %u messages\n", txCycle, txCount);
    }
  }
  else if (config_data.debug_level > 0) {
    gCatena.SafePrintf("message cycle time %u seconds indefinitely\n", txCycle);
  }
  gTxCycle = txCycle;
  gTxCycleCount = txCount;
 }
 /* process "application hello" -- args are ignored */
 // argv[0] is "hello"
 // argv[1..argc-1] are the (ignored) arguments
@ -1294,7 +1143,6 @@ cCommandStream::CommandStatus cmdHello(cCommandStream * pThis, void *pContext, i
  return cCommandStream::CommandStatus::kSuccess;
 }
 cCommandStream::CommandStatus cmdGetCalibrationSettings(cCommandStream * pThis, void *pContext, int argc, char **argv)
 {
  pThis->printf("{\n");
@ -1359,20 +1207,33 @@ cCommandStream::CommandStatus cmdCalibrateZeroScaleB(cCommandStream * pThis, voi
  return cCommandStream::CommandStatus::kSuccess;
 }
 cCommandStream::CommandStatus cmdCalibrateScales(cCommandStream * pThis, void *pContext, int argc, char **argv)
 {
  String s_cal_w1_0(argv[1]);
  String s_cal_w1_factor(argv[2]);
  String s_cal_w2_0(argv[3]);
  String s_cal_w2_factor(argv[4]);
  config_data.cal_w1_0 = s_cal_w1_0.toInt();
  config_data.cal_w1_factor = s_cal_w1_factor.toFloat();
  config_data.cal_w2_0 = s_cal_w2_0.toInt();
  config_data.cal_w2_factor = s_cal_w2_factor.toFloat();
  gCatena.getFram()->saveField(cFramStorage::kAppConf, (const uint8_t *)&config_data, sizeof(config_data));
  pThis->printf("{ \"msg\": \"calibrate_scales was successful\" }\n");
  return cCommandStream::CommandStatus::kSuccess;
 }
 cCommandStream::CommandStatus cmdCalibrateScaleA(cCommandStream * pThis, void *pContext, int argc, char **argv)
 {
  String w1_gramm(argv[1]);
  long weight1;
-  if (w1_gramm == "NA") {
+  setup_scales();
-    // scale a is not connected
+  weight1 = ReadScale('A');
-    config_data.cal_w1_factor = 1.0;
+  config_data.cal_w1_factor = (float)((weight1 - config_data.cal_w1_0) / w1_gramm.toFloat());
    config_data.cal_w1_0 = NOT_ATTACHED;
  } else {
    setup_scales();
    weight1 = ReadScale('A');
    config_data.cal_w1_factor = (float)((weight1 - config_data.cal_w1_0) / w1_gramm.toFloat());
  }
  gCatena.getFram()->saveField(cFramStorage::kAppConf, (const uint8_t *)&config_data, sizeof(config_data));
@ -1386,15 +1247,9 @@ cCommandStream::CommandStatus cmdCalibrateScaleB(cCommandStream * pThis, void *p
  String w2_gramm(argv[1]);
  long weight2;
-  if (w2_gramm == "NA") {
+  setup_scales();
-    // scale b is not connected
+  weight2 = ReadScale('B');
-    config_data.cal_w2_factor = 1.0;
+  config_data.cal_w2_factor = (float)((weight2 - config_data.cal_w2_0) / w2_gramm.toFloat());
    config_data.cal_w2_0 = NOT_ATTACHED;
  } else {
    setup_scales();
    weight2 = ReadScale('B');
    config_data.cal_w2_factor = (float)((weight2 - config_data.cal_w2_0) / w2_gramm.toFloat());
  }
  gCatena.getFram()->saveField(cFramStorage::kAppConf, (const uint8_t *)&config_data, sizeof(config_data));
--- a/mini_beieli_node.h
+++ b/mini_beieli_node.h
@ -56,7 +56,7 @@ enum {
  |
  \****************************************************************************/
-static const int32_t fwVersion = 20200529;
+static const int32_t fwVersion = 20200804;
 static const byte INIT_PACKAGE_INTERVAL = 100;  // send an init package every 100 packages;
 static const byte MAX_VALUES_TO_SEND = 8;
@ -65,7 +65,8 @@ static const uint8_t LORA_DATA_VERSION = 1;
 static const uint8_t LORA_DATA_VERSION_FIRST_PACKAGE = 128;
 static const uint32_t PRESSURE_OFFSET = 825;
 static const uint16_t SEND_DIFF_THRESHOLD_5GRAMS = 20;   // when weight changes by 100g, then send data
-static const long NOT_ATTACHED = -2147483648;
+static const long NOT_PLAUSIBLE_16 = 65535;
 static const long NOT_PLAUSIBLE_32 = 2147483647;
 static const byte INIT_PACKETS = 5;
 // must be 64 bytes long (size of kAppConf)
--- a/mini_beieli_node_nau7802.h
+++ b/mini_beieli_node_nau7802.h
@ -10,7 +10,6 @@
 #define SAMPLES 5
 NAU7802 myScale; //Create instance of the NAU7802 class
 byte debug_level;
@ -27,14 +26,10 @@ bool InitializeScales()
  result = myScale.reset(); //Reset all registers
  result &= myScale.powerUp(); //Power on analog and digital sections of the scale
  result &= myScale.setIntPolarityHigh();
  result &= myScale.setLDO(NAU7802_LDO_3V3); //Set LDO to 3.3V
  result &= myScale.setGain(NAU7802_GAIN_128); //Set gain to 128
  result &= myScale.setSampleRate(NAU7802_SPS_40); //Set samples per second to 40
  result &= myScale.setRegister(NAU7802_ADC, 0x30); //Turn off CLK_CHP. From 9.1 power on sequencing.
  result &= myScale.clearBit(NAU7802_PGA_PWR_PGA_CAP_EN, NAU7802_PGA_PWR);
  //result &= myScale.setRegister(NAU7802_OTP_B1, 0x30);
  //result &= myScale.setRegister(NAU7802_PGA, NAU7802_PGA_OUT_EN | NAU7802_PGA_CHP_DIS);
  result &= myScale.calibrateAFE(); //Re-cal analog front end when we change gain, sample rate, or channel
@ -47,7 +42,7 @@ bool SetupScales(byte dbg_level)
  if (debug_level > 0) {
    gCatena.SafePrintf("SetupScales start\n");
  }
-//  pinMode(interruptPin, INPUT);
+  //  pinMode(interruptPin, INPUT);
  if (!myScale.begin(Wire, false))
  {
@ -78,7 +73,7 @@ long ReadScale(char channel)
  } else {
    channelNumber = NAU7802_CHANNEL_2;
  }
-  long startTime = millis();
+  unsigned long startTime = millis();
  myScale.setChannel(channelNumber);
  bool calibrate_success = myScale.calibrateAFE();
  if (! calibrate_success) {
@ -93,34 +88,37 @@ long ReadScale(char channel)
  int const num_scale_readings = SAMPLES; // number of instantaneous scale readings to calculate the median
  // we use the median, not the average, see https://community.particle.io/t/boron-gpio-provides-less-current-than-electrons-gpio/46647/13
-  long readings[num_scale_readings];  // create arry to hold readings
+  long readings[num_scale_readings];  // create array to hold readings
  for (int i = 0; i < num_scale_readings; i++) {
    //while (digitalRead(interruptPin) == LOW) {
-    long mytimer = millis();
+    unsigned long mytimer = millis();
-    while (! myScale.available()) {
+    int timeouts = 0;
    while (! myScale.available() && (timeouts < 3)) {
      // we set a timeout of 10 seconds for the measurement...
      if ((millis() - mytimer) > 10000) {
        timeouts = timeouts + 1;
        // Timeout reading scale...
        Wire.endTransmission(true);
        delay(50);
        InitializeScales();
        if (debug_level > 0) {
          gCatena.SafePrintf("Timeout while reading scale...\n");
        }
        break;
      }
-      delay(1);
+      delay(50);
    }
    long reading;
    if (myScale.available()) {
-      reading = myScale.getReading();  
+      reading = myScale.getReading();
-      readings[i] = reading;  
+      readings[i] = reading;
    }
    if (debug_level > 0) {
      gCatena.SafePrintf("Reading: %d\n", reading);
    }
-    delay(10);
+    delay(50);
  }
-  long duration = millis() - startTime;
+  unsigned long duration = millis() - startTime;
  res = median(readings, num_scale_readings); // calculate median
  if (debug_level > 0) {
Author	SHA1	Message	Date
Joerg Lehmann	cee3752349	some changes	2022-05-21 17:40:50 +02:00
Joerg Lehmann	c3aa3b7845	with fixed ADC code	2020-08-04 16:19:15 +02:00
Joerg Lehmann	3bb6edd1e8	only format code	2020-08-04 16:16:30 +02:00
Joerg Lehmann	0aa2c11402	try with other nau7802 settings because of rare wrong readings	2020-07-21 14:27:58 +02:00
Joerg Lehmann	7ef7d25693	try some nau7802 settings because of rare wrong readings	2020-07-21 10:33:14 +02:00
Joerg Lehmann	1f0072797f	millis() is unsigned long	2020-07-14 19:45:25 +02:00
Joerg Lehmann	cfaccfb14a	plausibility checks, eliminiate NOT_ATTACHED	2020-07-01 13:11:56 +02:00
Joerg Lehmann	90782229d5	fix bug	2020-07-01 11:11:16 +02:00
Joerg Lehmann	363e8ecc23	read sensors a second time if values do not seem plausible	2020-07-01 11:05:25 +02:00
Joerg Lehmann	924ec0719f	handle scale timeouts better	2020-06-30 09:51:57 +02:00
Joerg Lehmann	3cf651b338	bug fix	2020-06-29 21:50:23 +02:00
Joerg Lehmann	0c553eed56	confirmed only if big difference in weight	2020-06-29 21:13:36 +02:00
Joerg Lehmann	fecc1bf67b	fix bug with last_values	2020-06-29 20:51:59 +02:00
Joerg Lehmann	ddec85f57e	fix bug with last_values	2020-06-29 20:10:04 +02:00
Joerg Lehmann	2ebcac04b7	enhance debug message	2020-06-29 17:57:01 +02:00
Joerg Lehmann	592bccdeb5	wait longer for sending to happen	2020-06-29 17:09:11 +02:00
Joerg Lehmann	3028836e2f	try to make measurements more stable...	2020-06-29 16:54:59 +02:00
Joerg Lehmann	f846c0d82a	README update	2020-06-29 15:59:46 +02:00
Joerg Lehmann	875b1fef02	do not go to deep sleep if we do a stop_iterations	2020-06-12 19:54:43 +02:00
Joerg Lehmann	9cc59aadbb	new release with patched library Catena-Arduino-Platform	2020-06-12 15:46:22 +02:00
Joerg Lehmann	22982235fb	do not send on first position	2020-06-08 20:40:57 +02:00
Joerg Lehmann	23de8b8f4b	use SF12 for initial Join	2020-06-08 16:06:52 +02:00
Joerg Lehmann	f0b4b0d286	add delay after wakeup of deep sleep; add command calibrate_scales	2020-06-08 14:29:34 +02:00
Joerg Lehmann	3a8764dcb4	avoid recursion	2020-06-06 19:34:47 +02:00
Joerg Lehmann	57d795c36b	20200605	2020-06-06 08:37:28 +02:00
Joerg Lehmann	d0a173a54a	20200604	2020-06-04 20:16:01 +02:00
Joerg Lehmann	a8fe52fa0e	reduce timeout again to 300sec, but sleep 10sec after timeout	2020-06-03 17:05:46 +02:00
Joerg Lehmann	eb4da9d637	add debugging info, bug fix	2020-06-03 16:04:47 +02:00
Joerg Lehmann	a4c0c71e54	README: patch arduino-lmic to use SF10	2020-06-03 10:37:26 +02:00
Joerg Lehmann	fcfc596506	increase timeout from 300 to 900 seconds	2020-06-03 08:56:10 +02:00
Joerg Lehmann	59ce7ee44d	20200602	2020-06-02 21:21:05 +02:00
Joerg Lehmann	f8909fc353	print LMIC.opmode before sleep	2020-06-01 19:31:36 +02:00
Joerg Lehmann	ab86c843b1	cancel transactions at timeout	2020-06-01 19:04:39 +02:00
Joerg Lehmann	6d3053d8ad	try to make it more stable...	2020-06-01 12:57:54 +02:00
Joerg Lehmann	85b0f6db06	refactor	2020-05-30 20:11:19 +02:00
Joerg Lehmann	0c5c673e5e	add delay, see https://github.com/mcci-catena/arduino-lmic/issues/547	2020-05-30 18:01:13 +02:00