Lobaro Pressure or Lobaro Pressure and Temperature Sensor

Lobaro Platform Device Type: lobaro-pegelsonde-hybrid

Select the correct sensor by checking the cable flag. The Pressure and Temperature sensor got a "P+T" marking.

Lobaro Pressure and Temperature Sensor	Lobaro Pressure Sensor	KELLER Series 26X
Lobaro article: #3000625	Lobaro article: ~~#3000588~~ (discontinued)	Lobaro article: #3000701

0 - 15 mH2O (other lengths on request) Accuracy: +/- 0.25% FSO (Fully Scale Output) Drift: +/- 0.3% FSO per year	0 - 15 mH2O Accuracy: 0.5% +/- FSO (Fully Scale Output) Drift: +/- 0.3% FSO per year	Keller Website White=GND Black =+Vcc Blue=RS485+ Yellow=RS485-
Red = VCC, Green = GND, RS485A = Yellow, RS485B = Blue

Lobaro Pressure and Temperature Sensor

To read out the pressure & temperature probe, the Hybrid Modbus Gateway must be configured as follows:

Parameter	Value	Comment
`WAN`	`lorawan`	For LoRaWAN OTAA usage.
`PlFmt`	5	Sets the payload to a short format.
`MbCmd`	0 0/15 * * * *:R,9600,8N1:010300160002,010300260002,fa0400050001	`010300160002` - Read register 22-23 (pressure) `010300260002` - Read register 38-39 (temperature) `FA0400050001` - Read internal register 5 (vBat) The CRON Expressions can be adjusted to set time of sensor reading.
`PowerOnDelay`	3000	Battery variant only. Sets time (in ms) between activating sensor power and reading value (time for sensor to be ready).

Modbus Register Mapping

The probe is a Modbus slave with the following registers:

Modbus Command: <Slave Address (1)><Function (1)><Address (2)><Length (2)>

Length = Register count -> 1 Register = 2 Bytes
Function
- 0x03 = Read Holding Register
- 0x04 = Read Input Register
- 0x06 = Write Holding Register

Address	Function	Bytes	Data Scope	Description
0x0000	0x03, 0x06	2	1-255	Slave Address
0x0001	0x03, 0x06	2	0-1200 1-2400 2-4800 3-9600 4-19200 5-38400 6-57600 7-115200	Baud rate
0x0002	0x03, 0x06	2	0 -No 1- Odd 2 - Even	No check Odd check Even check
0x0003	0x03	2	0- kpa 1- Mpa 2- ma 3- % 4- Inh2o 5- FtH2o 6- mmH2o 7- mmHg 8- psi 9- bar 10- mBar 11- g/cm² 12- kg/cm² 13- Pa 14- Torr 15- Atm 16- Null 17- M 18- cm 19- mm 20-InHg 21- mHg 22- MH20 23- °C	Pressure unit
0x0004	0x03	2	0 -#### 1- ###.# 2 - ##.## 3 - #.### 4 - #.####	Decimal point stands for 0-4 digits decimal points
0x0005	0x03	2	0-30	Filtering Coefficient
0x0016-0017	0x03	4	4 byte float	Measurement Pressure output value
0x0018-0019	0x03, 0x06	4	4 byte float	Master variable of Pressure offset
0x001A-001B	0x03	4	4 byte float	Range minimum of Pressure Transmitter
0x001C-001D	0x03	4	4 byte float	Range maximum of Pressure Transmitter
0x001E-001F	0x03	4	4 byte float	Range minimum of Pressure Sensor
0x0020-0021	0x03	4	4 byte float	Range maximum of Pressure Sensor
0x0026-0027	0x03	4	4 byte float	Measurement Temperature output value
0x00A6-00A7	0x06	4	4 byte float	Zero Clearing value of Pressure Transmitter
0xFFFF	0x06	2	0 - save to user area	Save data to user area
0xFFFC	0x06	2	0 - factory reset	Restore to factory status (user settings and calibration data)

Data Uplink (Port 20)

Bytes | 0 .    | 1 . 2 . 3 . 4 . | 5 . 6 . 7 . 8 . | 9 . 10 . |
------+--------+-----------------+-----------------+----------+
Field | Header | Pressure        | Temperature     | Voltage  |

All values are encoded big-endian

Field	Type	Value
Header	`uint8`	`0x00` on success, `0x80` if an error occurred
Pressure	`float32`	Pressure in `mH2O`, `ffffffff` on error.
Temperature	`float32`	Temperature in `°C`, `ffffffff` on error.
Voltage	`uint16`	Voltage in mV, `ffff` on error

010300160002

Example

# Example of a successful measurement
'003d94ce4541b7a5120e2a'
  '00'       -> Successful readout
  '3d94ce45' -> 0.073 mH2O
  '41b7a512' -> 22.96 °C
  '0e2a'     -> 3626 mV / 3.626 V

# Example
'80ffffffffffffffff'
  '80'       -> An error occurred.
  'ffffffff' -> Pressure could not be read.
  'ffffffff' -> Temperature could not be read.
  'ffff'     -> Voltage could not be read.

Reference Parser

see below

Lobaro Pressure Sensor

Reading from the Lobaro Pressure Sensor using the Hybrid Gateway can be done by setting the following parameters in the configuration:

Parameter	Value	Comment
`WAN`	`lorawan`	For LoRaWAN OTAA usage.
`PlFmt`	5	Sets the payload to a short format.
`MbCmd`	0 0/15 * * * *:R,9600,8N1:010300040001,fa0400040001,fa0400050001	010300040001 - Read register 4 (pressure) fa0400040001 - Read internal register 4 (temperature in box) fa0400050001 - Read internal register 5 (vBat) The CRON Expressions can be adjusted to set time of sensor reading.
`PowerOnDelay`	3000	Battery variant only. Sets time (in ms) between activating sensor power and reading value (time for sensor to be ready).

Modbus Register Mapping

The probe is a Modbus slave with the following registers:

Modbus Command: <Slave Address (1)><Function (1)><Address (2)><Length (2)>

Length = Register count -> 1 Register = 2 Bytes
Function
- 0x03 = Read Holding Register
- 0x06 = Write Holding Register

Address	Function	Bytes	Data Scope	Description
0x0000	0x03, 0x06	2	1-255	Slave Address
0x0001	0x03, 0x06	2	0-1200 1-2400 2-4800 3-9600 4-19200 5-38400 6-57600 7-115200	Baud rate
0x0003	0x03	2	0 -#### 1- ###.# 2 - ##.## 3 - #.###	Decimal point stands for 0-3 digits decimal points
0x0002	0x03	2	0- Mpa/℃ 1- Kpa 2- Pa 3- Bar 4- Mbar 5- kg/cm2 6- psi 7- mh2o 8- mmh2o	Pressure unit
0x0004	0x03	2	-32768-32767	Measurement output value
0x0005	0x03	2	-32768-32767	Zero point of transmitter range
0x0006	0x03	2	-32768-32767	Full point of transmitter range
0x000c	0x03, 0x06	2	-32768-32767	Zero point offset value, generally factory sets as 0
0x000F	0x06	2	0 - save to user area
0x0010	0x06	2	1 - factory reset

Data Uplink LoRaWAN (Port 20)

Bytes | 0 .    | 1 . 2 .  | 3 . 4 .     | 5 . 6 . |
------+--------+----------+-------------+---------|
Field | Header | Pressure | Temperature | Voltage |

All values are encoded big-endian

Field	Type	Value
Header	`uint8`	`0x00` on success, `0x80` if an error occurred
Pressure	`int16BE`	Pressure in mmH2O
Temperature	`int16BE`	Temperature in °C inside Bridge
Voltage	`uint16BE`	Voltage in mV, `ffff` on error

Example

# Example of a successful measurement
'000211001a0e2a'
  '00'           -> Successful readout
  '0211' -> 529  -> 0.529 mH2O
  '001a' -> 26   -> 26°C (inside Box)
  '0e2a' -> 3626 -> 3626 mV / 3.626 V

Keller PR26X

Configuration

Connected pressure sensor probe from Keller Druckmesstechnik PR26X series.

Parameter	Value	Comment
`WAN`	`lorawan`	For LoRaWAN OTAA usage.
`PlFmt`	5	Sets the payload to a short format.
`MbCmd`	0 0 * * * *:R,9600,8N1:010300020002,010300080002,FA0400050001	Reads four Registers: 2 + 3 (Float, Pressure in Bar) and 8 + 9 (Float, Probe Temperature) + Device battery voltage
`PowerOnDelay`	1500	Battery variant only. Sets time (in ms) between activating sensor power and reading value (time for sensor to be ready).

Example Modbus response

Hex to float converter: https://gregstoll.com/~gregstoll/floattohex/

Pressure (0x3f75f07b):

Temperature (0x41b5c079):

Data Uplink (Port 20)

Bytes | 0 .    | 1 . 2 . 3 . 4 . | 5 . 6 . 7 . 8 . | 9 . 10 . |
------+--------+-----------------+-----------------+----------+
Field | Header | Pressure        | Temperature     | Voltage  |

All values are encoded big-endian

Field	Type	Value
Header	`uint8`	`0x00` on success, `0x80` if an error occurred
Pressure	`float32`	Pressure in `Bar`, `ffffffff` on error.
Temperature	`float32`	Temperature in `°C`, `ffffffff` on error.
Voltage	`uint16`	Voltage in mV, `ffff` on error

Reference Parser (All variants, LoRaWAN only works with default config for MbCmd!)

Pressure Probe Parser

/**
 * Parser for Lobaro Pressure Probe via LoRaWAN (hybrid gateway).
 * Usable for Pressure Probe as or with Presure+Temperature Probe.
 * Works with TTN, ChirpStack, or the Lobaro Platform.
 */
function signed(val, bits) {
    // max positive value possible for signed int with bits:
    var mx = Math.pow(2, bits-1);
    if (val < mx) {
        // is positive value, just return
        return val;
    } else {
        // is negative value, convert to neg:
        return val - (2 * mx);
    }
}
function int16_BE(bytes, idx) {
    bytes = bytes.slice(idx || 0);
    return signed(bytes[0] << 8 | bytes[1] << 0, 2*8);
}
function uint16_BE(bytes, idx) {
    bytes = bytes.slice(idx || 0);
    return bytes[0] << 8 | bytes[1] << 0;
}
function uint32_BE(bytes, idx) {
    bytes = bytes.slice(idx || 0);
    return bytes[0] << 24 | bytes[1] << 16 | bytes[2] << 8 | bytes[3] << 0;
}
function float32FromInt(asInt) {
    var sign = (asInt >> 31) == 0 ? 1 : -1;
    var exponent = ((asInt >> 23) & 0xFF) - 127;
    var significand = (asInt & ~(-1 << 23));
    if (exponent === 128)
        return null;
        // return sign * ((significand) ? Number.NaN : Number.POSITIVE_INFINITY);
    if (exponent === -127) {
        if (significand === 0) return sign * 0.0;
        exponent = -126;
        significand /= (1 << 22);
    } else {
        significand = (significand | (1 << 23)) / (1 << 23);
    }
    return sign * significand * Math.pow(2, exponent);
}
function float32_BE(bytes, idx) { return float32FromInt(uint32_BE(bytes, idx)); }
  
/**
 * TTN decoder function.
 */
function Decoder(bytes, port) {
    var vals = {};
    if( port == 20 ){
        if (bytes.length==5) {
            // Pressure Probe without temperature sensor and Bridges internal Temperature
            vals["error"] = !!(bytes[0]&0x80);
            vals["pressure"] = int16_BE(bytes, 1)/1000;
            vals["temperature"] = int16_BE(bytes, 3);
        }  else if (bytes.length==7) {
            vals["error"] = !!(bytes[0]&0x80);
            vals["pressure"] = int16_BE(bytes, 1)/1000;
            vals["temperature"] = int16_BE(bytes, 3);
            vals["voltage"] = uint16_BE(bytes, 5) / 1000;
        } else if (bytes.length==9) {
            vals["error"] = !!(bytes[0]&0x80);
            // pressure in mH2O
            vals["pressure"] = float32_BE(bytes, 1);
            // temperature in Degree Celsius
            vals["temperature"] = float32_BE(bytes, 5);
        } else if (bytes.length==11) {
            vals["error"] = !!(bytes[0]&0x80);
            // pressure in mH2O
            vals["pressure"] = float32_BE(bytes, 1);
            // temperature in Degree Celsius
            vals["temperature"] = float32_BE(bytes, 5);
            vals["voltage"] = uint16_BE(bytes, 9) / 1000;
        }
    }
     
    if (port === 64 && bytes.length == 13) { // status packet
        vals["Firmware Identifier"] =  String.fromCharCode(bytes[0]) + String.fromCharCode(bytes[1]) + String.fromCharCode(bytes[2]);
        vals["FirmwareVersion"] = bytes[3] + '.' + bytes[4] + '.' + bytes[5];
        vals["status"] = bytes[6];
        vals["reboot reason"] = bytes[7];
        vals["final words"] = bytes[8];
        vals["voltage"] = uint16_BE(bytes,9)/1000.0
        vals["temperature"] =  int16_BE(bytes,11)/10.0;
    }
    return vals;
}
 
function NB_ParseModbusQuery(input){
  vals = {};
  
  for( var i = 0; i< input.d.batch.length; i++ ){
    if (input.d.batch[i].cmd == "AQMAFgAC"){
      vals["pressure"] = float32_BE(bytes(atob(input.d.batch[i].rsp)),3);
    }
    if (input.d.batch[i].cmd == "AQMAJgAC"){
      vals["temperature"] = float32_BE(bytes(atob(input.d.batch[i].rsp)),3);
    }
    
    // else: keller
    if (input.d.batch[i].cmd == "AQMAAgAC"){
      // convert to mH2O
      vals["pressure"] = float32_BE(bytes(atob(input.d.batch[i].rsp)),3)*10.197442889221;
    }
    if (input.d.batch[i].cmd == "AQMACAAC"){
      vals["temperature"] = float32_BE(bytes(atob(input.d.batch[i].rsp)),3);
    }
      // vbat
   if (input.d.batch[i].cmd == "+gQABQAB"){
      vals["vBat"] = int16_BE(bytes(atob(input.d.batch[i].rsp)),3)/1000.0;
    }
  
    // internal temperature
     if (input.d.batch[i].cmd == "+gQABAAB"){
      vals["temperatureInt"] = int16_BE(bytes(atob(input.d.batch[i].rsp)),3);
    }
  }
  
  return vals;
}
   
/**
 * TTN V3 Wrapper
 */
function decodeUplink(input) {
   return {
    data: {
      values: Decoder(input.bytes, input.fPort)
    },
    warnings: [],
    errors: []
  };
}
   
function NB_ParseDeviceQuery(input) {
  for (var key in input.d) {
      var v = input.d[key];
      switch (key) {
          case "temperature":
              v = v / 10.0;
              Device.setProperty("device.temperature", v);
              continue;
          case "vbat":
              v = v / 1000.0;
              Device.setProperty("device.voltage", v);
              continue;
      }
      Device.setProperty("device." + key, v);
  }
  return null;
}
   
function NB_ParseConfigQuery(input) {
  for (var key in input.d) {
    Device.setConfig(key, input.d[key]);
  }
    return null;
}
   
function NB_ParseStatusQuery(input) {
    NB_ParseDeviceQuery(input);
    return null;
}
   
/**
 * ChirpStack decoder function.
 */
function Decode(fPort, bytes) {
    // wrap TTN Decoder:
    return Decoder(bytes, fPort);
}
   
/**
 * Lobaro Platform decoder function.
 */
function Parse(input) {
    if (input.i && input.d) {
      // NB-IoT
      var decoded = {};
      decoded = input.d;
      decoded.address = input.i;
      decoded.fCnt = input.n;
      
      var query = input.q || "data";
      
      switch (query) {
        case "config":
          return NB_ParseConfigQuery(input);
        case "device":
          return NB_ParseDeviceQuery(input);     
        case "modbus":
          return NB_ParseModbusQuery(input);
        case "status":
          return NB_ParseStatusQuery(input);
        default:
      }
      return decoded;
    }
    
    
    var data = bytes(atob(input.data));
    var port = input.fPort;
    return Decoder(data, port);
}

Page tree

Pressure Sensor Application

Lobaro Pressure or Lobaro Pressure and Temperature Sensor

Lobaro Pressure and Temperature Sensor

Modbus Register Mapping

Data Uplink (Port 20)

Example

Reference Parser

Lobaro Pressure Sensor

Modbus Register Mapping

Data Uplink LoRaWAN (Port 20)

Example

Keller PR26X

Configuration

Example Modbus response

Data Uplink (Port 20)

Reference Parser (All variants, LoRaWAN only works with default config for MbCmd!)