User Manual for inveo models including: DS18B20 Nano Temperature Sensor POE, DS18B20, Nano Temperature Sensor POE
1 Preliminary information. 2 Application of the device. 3 Warranty and liability of the manufacturer. 4 Safety guidelines. 5 Construction of the device. 6 Configuration of the device. 7 The device functions.
User manual Nano Temperature Sensor POE Nano Temp Sensor Soft >= 1.21 INVEO s.c. ul. Rzemieślnicza 21 43-340 Kozy tel: 48 33 444 65 87 www.inveo.com.pl
1 Preliminary information. 2 Application of the device. 3 Warranty and liability of the manufacturer. 4 Safety guidelines. 5 Construction of the device. 6 Configuration of the.. View
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DocumentDocumentUser manual Nano Temperature Sensor POE
Nano Temp Sensor
Soft >= 1.21 INVEO s.c. ul. Rzemielnicza 21 43-340 Kozy tel: +48 33 444 65 87 www.inveo.com.pl info@inveo.com.pl
Dear Customer!
Thank you very much for choosing our product. Before its use, please read these instructions carefully. Here you find the most appropriate ways of dealing with this device, the basic principles of safety and maintenance. Please, also keep the user manual so that you can read it during later use.
Attention! The manufacturer is not liable for any damage caused by improper use of the device which differ from its intended purpose, or improper handling, as well as a fault of driver resulting from improper use.
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Contents:
1 PRELIMINARY INFORMATION...................................................................................................................4
2 APPLICATION OF THE DEVICE..................................................................................................................5
3 WARRANTY AND LIABILITY OF THE MANUFACTURER...................................................................5
4 SAFETY GUIDELINES.....................................................................................................................................6 4.1 STORAGE, WORK AND TRANSPORT CONDITIONS.........................................................................................................6 4.2 INSTALLATION AND USE OF THE DEVICE..................................................................................................................6 4.3 DECOMMISSIONING OF THE DEVICE.........................................................................................................................6
5 CONSTRUCTION OF THE DEVICE..............................................................................................................7 5.1 NANO TEMPERATURE SENSOR POE.......................................................................................................................7 5.2 NANO TEMP......................................................................................................................................................9
6 CONFIGURATION OF THE DEVICE.........................................................................................................11 6.1 CHANGING THE DEVICE'S IP ADDRESS BY DISCOVERER APPLICATION.........................................................................11 6.2 CHANGING THE PC'S SUBNET ADDRESS, FOR THE DEVICE CONFIGURATION..................................................................12 6.3 SECURITY SETTINGS AND ADMINISTRATION............................................................................................................14
7 THE DEVICE FUNCTIONS...........................................................................................................................15 7.1 PREVIEW OF THE MEASURED TEMPERATURE...........................................................................................................15 7.2 ALARMS..........................................................................................................................................................15 7.3 DESTINATION CLIENT........................................................................................................................................17 7.4 SNMP CONFIGURATION....................................................................................................................................21 7.5 WINDOWS COMMAND LINE SOFTWARE..................................................................................................................22 7.6 LINUX CONTROL PROGRAM.................................................................................................................................22 7.7 MODBUS TCP.................................................................................................................................................23 7.8 MQTT INVEO.................................................................................................................................................24 7.9 COMMUNICATION WITH MODULE USING HTTP......................................................................................................25 7.10 DESCRIPTION OF THE COMMUNICATION PROTOCOL................................................................................................27
8 COMMUNICATION WITH THE MODULE FROM THE EXTERNAL NETWORK...........................28
9 CHECKING THE IP ADDRESS.....................................................................................................................28
10 DHCP................................................................................................................................................................28
11 RESTORING FACTORY DEFAULTS........................................................................................................29
12 FIRMWARE UPDATE..................................................................................................................................29
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1 Preliminary information
Before starting work with the device, read The User manual and follow the instructions contained therein!
Description of visual symbols used in this user manual:
This symbol is responsible for reviewing the appropriate place in the user instructions, warnings and important information. Failure to follow warnings could cause injury or damage to the device
Important information and guidelines
Following this guidelines makes the use of the device easier
Attention: The screenshots in this manual can be dissimilar from actual images at the time of the device purchase. Due to continuous development of the devices software, some of the functions may differ from these in the manual. The manufacturer claims no responsibility for any undesirable effects (misunderstanding) caused by changes of the software.
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2 Application of the device
NANO Temperature Sensor module is used to read temperature over different LAN protocols. The temperature readout is possible using built in www website, HTTP GET, Modbus TCP, SNMP and MQTT protocols. This module can communicate with other Inveo modules and e.g. trigger relay actions.
3 Warranty and liability of the manufacturer
The manufacturer provides a 2-year warranty on the device. The manufacturer also provides post-warranty service for 10 years from the date of the introducing the device on the market. The warranty covers all defects in material and workmanship. The manufacturer undertakes to comply with the contract of guarantee, if the following conditions are met:
all repairs, alterations, extensions and device calibrations are performed by the manufacturer or authorized service,
supply network installation meets applicable standards in this regard, the device is operated in accordance with the recommendations outlined in this
manual, the device is used as intended.
The manufacturer assumes no responsibility for consequences resulting from improper installation, improper use of the device, not following this manual and the repairs of the device by individuals without permission.
This device doesn't contain serviceable parts.
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4 Safety guidelines
The device has been designed and built using modern electronic components, according to the latest trends in the global electronics. In particular, much emphasis was placed on ensuring optimum safety and reliability of control. The device has a housing with a highquality plastic.
4.1 Storage, work and transport conditions The device has to be stored in enclosed rooms which are free of caustic vapors and substances and also meet the requirements:
surrounding temperature from -30°C to +60°C, humidity from 25 to 90%, atmospheric pressure from 700 to 1060hPa.
The device working conditions: surrounding temperature from -10°C to +55°C, relative humidity from 30% to 75%, atmospheric pressure from 700 to 1060hPa.
Recommended transport conditions: surrounding temperature from -40°C to +85°C, relative humidity from 5% to 95%, atmospheric pressure from 700 to 1060hPa.
4.2 Installation and use of the device The device should be used following the guidelines shown in next part of the user manual.
4.3 Decommissioning of the device When it becomes necessary to recycle the device (for instance, to decommission the device from service), please contact the manufacturer or its representative, who are obliged to respond, appropriately, i.e. collecting the device from the user. You can also ask the companies involved in recycling of electrical or computer equipment. Under no circumstances should you place the device along with other waste material.
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5 Construction of the device
5.1 Nano Temperature Sensor PoE
Technical data:
Power supply:: PoE: 33-57V POE IEEE 802.3af DC: 10-24VDC (screw terminals 3,5mm) Power consumption: max 1,5W
Inputs: 1 input:
input type: 1-wire bus type of sensor: DS18B20 temperature measured: -55°C do +125°C screw connection
Communication: 1 port Ethernet:
10Mbps PoE IEEE 802.3af
Housing: IP Code: 30 Dimensions:
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General features:
The device has a 7-segment display.
There are several ways to communicate with the module: · using built in WWW server via any web browser, · Windows / Linux command line programs, · MODBUS TCP protocol, · SNMP protocol, · MQTT Inveo protocol, · User application TCP protocol available for user.
Description of the module connectors:
· LAN LAN connection and PoE IEEE 802.3af power supply, · RESET switch used to enabling DHCP service, checking the current IP address
and restoring the module to the factory settings.
· 1-WIRE screw connection for connection of the temperature sensor, · POWER power connector. An additional power connector used in the event of a
PoE power failure. Supply voltage 10-24VDC.
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5.2 Nano Temp
Technical data:
Power supply: The module is adapted to 12-24VDC power supply. Power is supplied through the passive PoE adapter.
Inputs: 1 input:
input type: 1-wire bus type of sensor: DS18B20 temperature measured: -55°C do +125°C screw connection
Communication: 1 port Ethernet:
10Mbps passive PoE 12-24VDC power supply
Housing: IP Code: 30 Dimensions:
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General features:
The device has two LEDs. LEDs indicate power supply and temperature reading. There are several ways to communicate with the module:
· using built in WWW server via any web browser, · Windows / Linux command line programs, · MODBUS TCP protocol, · SNMP protocol, · MQTT Inveo protocol, · User application TCP protocol available for user.
Description of the module connectors: · LAN LAN network and Passive PoE power supply, · RESET switch used to enabling DHCP service and restoring the module to the factory settings. · 1-WIRE screw connection for connection of the temperature sensor.
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6 Configuration of the device
The device when used for first time needs to be configured. There are two methods to do so. The network configuration can be easily changed by Inveo "Discoverer" (https://inveo.com.pl/software/) software:
6.1 Changing the device's IP address by Discoverer application When the "Discoverer" is opened and the relevant device is found, choose Interface list box and click on Change IP button.
In a new opened dialog box, settings such as IP address, MASK, GATEWAY, DNS1/DNS2 and the Host name can be changed.
Please save correct settings by choosing Change button.
If Remote Config is disabled (enabled by default), it is necessary to configure the device by changing the computer's subnet (chapter 6.2).
To enable the remote configuration it is necessary to enter Administration tab and mark Enable Remote Network Config.
Save the setup by selecting Save Config button.
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6.2 Changing the PC's subnet address, for the device configuration After the device is connected to a network, a subnet address of a PC which is connected to the same network has to be changed. To do so, go to the PC's MS Windows network configuration: Start->Control panel ->Network and Sharing Center->Network and Internet->Network Connections, choose the related controller and right click on ,,Properties". After selecting this option configuration window will show up:
Changing network settings in MS WINDOWS
Next choose "Internet Protocol (TCP/IP)", double click on it and enter following settings:
Illustrative TCP/IP protocol settings
After saving changes by clicking OK, open an Internet browser and enter in the browser's address line: 192.168.111.15. Default user name/password: admin/admin00
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In the Network tab it is possible to change LAN parameters.
To change the network settings, use the following fields: · Host Name NETBIOS name, · DHCP checking this box forces use of the address assigned by the DHCP server, · IP Address the IP address of the reader, · Gateway network gateway, · Subnet Mask IP subnet mask, · Gateway network gateway, · DNS1, DNS2 DNS servers addresses.
· Destination IP the IP address of the device in the M2M connection (chapter 7.3),
· Destination Port the listening port of the external device in the M2M connection.
After all changes, select Save Config.
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6.3 Security settings and administration The Administration settings allow for changing access password and to enable/disable particular services in the device.
Password change To change password, in the Current Password field write a current password. Next, in the New Password field write your new password and confirm it at Re-type Password field.
Service settings The device allows to choose which services are to be available. Selecting the check box next to the service name activates the selected service.
Enable Program Access a service of access by a computer program (Windows, Linux) and TCP / IP protocol operating on port 9761, Enable MODBUS TCP Protocol enables Modbus TCP server, Enable SNMP enables SNMP protocol supporting, Enable Destination Client connecting to a remote host service (chapter 7.3), Enable MQTT Inveo a service that sends data to the INVEO MQTT cloud, Enable Remote Network Config remote configuration (via the Discoverer application), Enable TFTP Bootloader enables a bootloader.
Attention: TFTP Bootloader and Remote Network Config ought to be disabled during normal work operation. It should be enabled for a firmware update only.
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7 The device functions
7.1 Preview of the measured temperature In the Home tab, the current temperature read from the sensor connected to the bus is displayed and the over temperature condition is signaled.
7.2 Alarms In the Channel tab, it is possible to set alarm thresholds. If the temperature is out of range, the alarm will be active.
Alarm Mode · Off alarm disabled, · Lower if the temperature is lower than value set in the Alarm Low field, the alarm will be active. · Higher if the temperature is higher than value set in the Alarm High field, the alarm will be active. · Lower or Higher if the temperature is lower than value set in the Alarm Low field or if the temperature is higher than value set in the Alarm High field, the alarm will be active.
Sensor Offset the value that will be added to the measured value.
All changes must be confirmed with the Save button.
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The occurrence of an alarm condition is signaled on the homepage of the module, and the display or LED is flashes.
If the alarm is active, the virtual output No. 1 is enable (<on>00000001</on>). The virtual output state is in the status.xml resource.
http://192.168.111.15/status.xml
<response> <prod_name>Nano-DS</prod_name> <sv>1.17</sv> <mac>54:10:EC:BB:61:17</mac> <out>00000000</out> <on>00000001</on> <in>00000000</in> <counter1>0</counter1> <temp1>18.8</temp1> </response>
Attention! If an alarm has occurred, return to normal device operation (without alarm signaling) will take place only after crossing the hysteresis zone equal to 1 degree Celsius. For example, if the Alarm Low is set to 20 degrees Celsius, the alarm will be activated when the temperature reaches 20 degrees and turns off when the temperature reaches 21 degrees Celsius.
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7.3 Destination Client Inveo devices as LanTick, Nano Temperature Sensor, Nano Digital Input, Nano Relay Output or others are able to send information data to the server or to another module with outputs using the TCP or UDP protocol. It means that this another module can react to activation of channel or when alarm occurs (Nano Sensors). The message is sent each time state is changed and additionally every 5 seconds.
Configuration of devices receiving messages (external devices) To enable the service, enter the Administration tab and select Enable Program Access and confirm with the Save Config button.
Configuration of devices sending alarm status messages To enable the service, enter the Administration tab and select Enable Destination Client and confirm with the Save Config button.
In the Network tab, fill in the Destination IP and Destination Port fields. The Destination IP field is an IP address of the external device or a server. The Destination Port field is a port number of the external device (9731 by default).
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Then, in the Channel tab select the appropriate output which will be enabled in the external device or select type of the message.
The user can choose the following fields: · TCP Ch:x the function uses the connection protocol i.e. the TCP protocol. Number Ch:x is selected output channel in an external device, e.g. LanTick, which will be enabled when the channel state of the local device changes. The TCP frame sends in the format #1,
· UDP Ch:x the function uses the connectionless protocol i.e. the UDP protocol. Number Ch:x is selected output channel in an external device, e.g. LanTick, which will be enabled when the channel state of the local device changes. The UDP frame sends in the format #1,
· Status sends the device channel status, TCP frame sent in the format #2,
· MAC+Status sends the MAC address of the device and current channel status, TCP frame sent in the format #3,
· HTTP GET sends the MAC address of the device current alarm status and temperature value, frame sent in the format #4.
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TCP frames formats Format #1 The frame in the format #1 is sent in binary form. An example TCP frame sent with active alarm and Dest:5 set
SOF CMD CH
F_ID ALARM !ALARM TEMP RES
0x0F 0x01 0x04 0xFF 0x01 0xFE 0x0F 0x00
RAW LSB
0x01
RAW MSB
0x57
CRC 0x7F
An example TCP frame sent with inactive alarm and Dest:5 set
SOF CMD CH
F_ID ALARM !ALARM TEMP RES
0x0F 0x01 0x04 0xFF 0x00 0xFF 0x0F 0x00
RAW LSB
0x01
RAW MSB
0x57
CRC 0x7F
Values RAW_LSB and RAW_MSB is the temperature read directly from the sensor. The temperature read off should be divided by 16
Value TEMP it's the temperature without the decimal part.
Calculation of CRC: CRC = (SOF+CMD+CH+F_ID+ALARM+!ALARM+TEMP+RES+RAW_LSB+RAW_MSB) MOD 256
Format #2 The frame #2 is sent as a string (STRING).
<ALARM>[SPACE]<TEMPERATURE> · ALARM value 1 means an alarm is active, 0 means an alarm is inactive · TEMPERATURE read temperature
Value in HEX
STRING
30 20 33 39 2E 35
0 39.5
Format #3 The frame #3 is sent as a string (STRING).
<MAC>[SPACE]<ALARM>[SPACE]<TEMPERATURE> · MAC network address of the module, · ALARM value 1 means an alarm is active, 0 means an alarm is inactive, · TEMPERATURA read temperature.
Value in HEX 35 34 31 30 45 43 36 35 35 30 32 31 20 30 20 34 36 2E 39
STRING 5410EC655021 0 46.9
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Format #4 Setting Client Mode to HTTP GET causes that the device sends data to the server in the form:
nano.php?mac=<MAC>&io=<Alarm>&cnt=<Temperature> · MAC MAC address, · Alarm value 1 means active alarm, 0 means inactive alarm, · Temperature counter temperature value.
An example of a frame received by the server: GET /nano.php?mac=123456789012&io=0&value=7
MAC address = 123456789012,
io=0,
the input is inactive
value=7,
the current temperature value 7
The TCP frame can be handled with your own software.
An example of using the netcat command for Linux: Format #1
Format #2
Format #3
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7.4 SNMP configuration The module is equipped with an SNMP v2c server. To enable this feature go to Administration tab and check Enable SNMP option.
The SNMP protocol allows to read the current value. The MIB file describing the structure can be downloaded the SNMP tab.
The basic parameters that can be read from the Nano Temperature Sensor module can be found in the table:
Name CH1_TEMP CH1_TEMPINT (integer) CH1_TEMPINT10 (temperature *10) CH1_ON (Alarm active)
Format STRING INTEGER INTEGER INTEGER
OID .1.3.6.1.4.1.42814.14.3.5.1.0 .1.3.6.1.4.1.42814.14.3.5.2.0 .1.3.6.1.4.1.42814.14.3.5.3.0 .1.3.6.1.4.1.42814.14.3.1.1.0
Module can send TRAP messages after alarm activation. Destination address should be entered in Trap IP Address 1 and Trap IP Address 2 fields.
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7.5 Windows command line software The module can be operated using windows command line software. To use the command line program, it is necessary to enable the Access program setting in the Administration tab.
Windows syntax: TCPRel.exe [Parameters]
Parameter -in=1 -host=[HOST] -port=[PORT] -readtemp
Description The number of the input being read The IP address of the module Module port Reading values from the sensor
Example: Reading the current value, the module has an address: 192.168.111.15 and listens on port 9761: TCPRel -in=1 -host=192.168.111.15 -port=9761 -readtemp
7.6 Linux control program To use the linux command line software, it is necessary to enable the Access program setting in the Administration tab.
Syntax is as follows: ./TcpRel.exe [Parameters]
Parameter
-i 1 -h [HOST] -p [PORT] -t
Description
The number of the input being read The IP address of the module Module port Reading values from the sensor
Example: Read temperature from module at IP address 192.168.111.15 and port 9761: ./tcprel -i 1 -h 192.168.111.15 -p 9761 -t
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7.7 Modbus TCP The device supports Modbus TCP protocol. The Modbus TCP server is available over LAN and listens on port 502.
Supported Modbus functions The device supports the following MODBUS functions: - 0x01 Read Coils, - 0x03 Read Holding Register, - 0x06 Write Single Register, - 0x0F Write Multiple Coils, - 0x10 Write Multiple Registers.
Modbus TCP Coils
Address
Name
1000
On1
1002
SensError
R/W R R
Description Alarm state Sensor error (0-ok, 1-error)
Modbus TCP Holding Registers
Address 4000 4001 4002
Name ThermostatL ThermostatH Alarm mode
R/W R/W R/W R/W
4004
Temperature x10
R
4005
Temperature Int
R
4006
Temperature Frac
R
4007
MAC 0
R
4008
MAC 1
R
4009
MAC 2
R
4010
MAC 3
R
4011
MAC 4
R
4012
MAC 5
R
4013
StoreConfig
W
Opis Lower alarm threshold Upper alarm threshold 1 OFF (disabled)
2 Lower
3 Higher
4 Lower or Higher Temperature x 10 (np. 10,5 st.C to 105) Integral part of temperature Decimal part of temperature MAC address MAC address MAC address MAC address MAC address MAC address Entering 144 will save to configuration to
EEPROM
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7.8 MQTT Inveo If the MQTT Inveo service has been enabled in the Administration tab, the module sends to mqtt.inveo.com.pl server the value of measured temperature every 1 minute and additionally at each change. Application configuration MQTT Client: Address: mqtt.inveo.com.pl Port: 1883 User name: nanouser User password: nanouser Topic: /nanoT/<MAC> After click [Show Info] the settings for the MQTT client will be displayed:
There are many applications on Android, IOS or PC that can display data sent by the module.
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7.9 Communication with module using HTTP Modules can be controlled using HTTP GET.
To read current state of the module refer to a resource such as http://192.168.111.15/status.xml
XML file consist all of the information: <response> <prod_name>Nano-DS</prod_name> <sv>1.20</sv> <mac>00:00:00:00:00:00</mac> <out>00000000</out> <on>00000000</on> <in>00000000</in> <counter1>0</counter1> <temp1>19.4</temp1> </response>
Section
<prod_name>PE-DS</prod_name> <sv>1.20</sv> <mac>00:00:00:00:00:00</mac> <out>00000000</out>
<on>00000000</on>
<in>00000000</in>
<counter1>0</counter1>
<temp1>21.3</temp1>
Description Type of the module
The firmware version MAC address
Output state (enabled/disabled), N/A in Nano Temperature Sensor
Status of virtual outputs:
00000001 means alarm state
Input state (Active/Inactive), N/A in Nano Temperature Sensor Counter inputs, N/A in Nano Temperature Sensor Temperature sensor reading Temperature is 21.3 degree
To read measured temperature only, refer to the resource temp1.txt. The temperature will be displayed in text form.
For example: http://192.168.111.17/temp1.txt
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Example of reading the measured value with the CURL command. Attention! Access to resource stat.php require authorization. Access to resources status.xml and temp1.txt do not require authorization. curl "http://192.168.111.15/temp1.txt" -w "\n"
curl "http://192.168.111.15/status.xml" -w "\n" 2>/dev/null | grep 'temp1' | awk -F "[><]" '/temp1/{print $3}'
curl -u admin:admin00 "http://192.168.111.15/stat.php" -w "\n" 2>/dev/null | grep 'prod_name' | awk -F "[><]" '/prod_name/{print $3}'
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7.10 Description of the communication protocol Nano Temperature Sensor communication data frame.
Byte number
1
Command
Byte name
SOF
dec Temperature
reading hex
15 0x0F
2
3
4
5
6
CMD Channel Data1 Data2 Data3
12
0
X
X
X
0x0C 0x00
X
X
X
7 Data4
X X
8
9
10 11
Data5 Data6 Data7 CRC Returns
2 bytes
X
X
X CRC + CRC
X
X
X
CRC
2 bytes + CRC
As default modules are listening on TCP port 9761.
Reading the current value from the temperature sensor.
SOF CMD CH
D1
D2
D3
D4
0x0F 0x0C 0x00 0x00 0x00 0x00 0x00
D5 0x00
D6 0x00
D7 0x00
CRC 0x1B
CRC = (BYTE) SUM (SOF+CMD+CH+D1..D7)
The device returns 2 bytes (current temperature) + CRC (sum of 2 bytes)
Examples:
Temperature value
The value returned by the module to port 9761
Convert to dec format
Converted temperature value
(dec/16)
dec -18,0 -5,1 26,5 33,8
2 bytes E0 FE AE FF A8 01 1E 02
CRC
hex
dec
DE FFFF-FEE0
287
AD FFFF-FFAE
81
A9
1A8
424
20
21E
542
dec -17,9375 -5,0625
26,5 33,875
The converted decimal value have to be divided by 16.
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8 Communication with the module from the external network
If the module is in a different LAN network than the computer connecting to it, port forwarding is required. Depending on the communication method used with the module, it is necessary to contact the Network Administrator and port forwarding:
Support via website and HTTP protocol: - port TCP 80
Service by a computer program or by your own application: - port TCP 9761
Support via MODBUS TCP: - port TCP 502
Support via SNMP protocol: - port UDP 161
9 Checking the IP address
Concerns only Nano Temperature Sensor PoE.
To check the current IP address of the device: 1. Press and hold the reset button until the display shows the four parts of the IP number, e.g. 192 168 111 15. 2. Release the reset button.
10 DHCP
To enable/disable DHCP service:
1. Press and hold RESET button 5 to 10 second. 2. Green LED will start flashing 2 times a second (Nano Temperature Sensor), the
display will show: dhcP (Nano Temperature Sensor PoE). 3. Release the reset button.
It is also possible to enable DHCP in the network configuration in the Network tab or through Discoverer application.
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11 Restoring factory defaults
To reset the device to factory settings: 1. Press and hold RESET button for 10 to 15 seconds 2. Green LED will start flashing 2 times a second (Nano Temperature Sensor), the display will show: rSt (Nano Temperature Sensor PoE). 3. Release the reset button.
With factory defaults restored the module settings are as follows: · DHCP: enabled · IP address: 192.168.111.15 · IP mask: 255.255.255.0 · User name: admin · Password: admin00
12 Firmware update
The device has the ability to update the firmware. The software update program is provided as a *.bin file.
Warning! Incorrect use of the update feature may damage the reader. Make sure that undisturbed power is provided to the device for duration of programming.
To update the software: · check the Enable TFTP Bootloader option, which is located in the Administration tab, · run the Windows command line (Start-> Run enter 'cmd' and confirm with the Enter key), · go to the directory where the .bin file is located · enter the command:
tftp -i <address_ip_of the reader> PUT file.bin
where: <address_ip_of the reader> is the IP Address of the reader file.bin the file with the update program
Programming takes 1-2 minutes. End of programming confirms the message 'File Transferred'.
For correct functioning of the reader, after the update operation the ,,Enable TFTP Bootloader" option has to be switched off.
Step-by-step instruction for firmware updates is available at https://inveo.com.pl.
The latest instructions and software are available on the site https://inveo.com.pl.
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