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{{Template:Networking_rutos_manual_fw_disclosure
{{Template: Networking_device_manual_fw_disclosure
| fw_version = {{{series}}}_R_00.02.04.1
| series = {{{series}}}
| series     = {{{series}}}
| name  = {{{name}}}
| fw_version ={{Template: Networking_device_manual_latest_fw
| series = {{{series}}}
| name  = {{{name}}}
}}
}}
}}
 
{{#ifeq: {{{series}}} | RUT9 |<br><i><b>Note</b>: <b>[[{{{name}}} Modbus (legacy WebUI)|click here]]</b> for the old style WebUI (FW version {{Template: Networking_device_manual_latest_fw | series = RUT9XX}} and earlier) user manual page.</i>|}}
{{#ifeq: {{{series}}} | RUT2 |<br><i><b>Note</b>: <b>[[{{{name}}} Modbus (legacy WebUI)|click here]]</b> for the old style WebUI (FW version {{Template: Networking_device_manual_latest_fw | series = RUT2XX}} and earlier) user manual page.</i>|}}
==Summary==
==Summary==


Line 9: Line 14:


This manual page provides an overview of the Modbus functionality in {{{name}}} devices.
This manual page provides an overview of the Modbus functionality in {{{name}}} devices.
{{#switch: {{{series}}}
| RUTX =
| RUTM =
| TRB1 =
| TRB2 =
| TRB2M =
| RUT9|RUT9M =
| #default =
<u><b>


Note:</b> On {{{name}}}, Modbus TCP Server/Client and MQTT Gateway is additional software that can be installed from the <b>System → [[{{{name}}} Package Manager|Package Manager]]</b> page.</u><br>}}
{{Template:Networking_rutos_manual_basic_advanced_webui_disclaimer
{{Template:Networking_rutos_manual_basic_advanced_webui_disclaimer
| series = {{{series}}}
| series = {{{series}}}
}}
}}


==Modbus TCP slave==
==Modbus TCP Server==


A <b>Modbus TCP slave</b> listens for connections from a master (client) and sends out a response or sets some system related parameter in accordance with the given query. This provides the user with the possibility to set or get system parameters.  
A <b>Modbus TCP Server</b> listens for connections from a TCP Client (client) and sends out a response or sets some system related parameter in accordance with the given query. This provides the user with the possibility to set or get system parameters.  


The figure below is an example of the Modbus TCP window section and the table below provides information on the fields contained in that window:
The figure below is an example of the Modbus TCP window section and the table below provides information on the fields contained in that window:


[[File:Networking_rutos_manual_modbus_modbus_tcp_slave_v2.png]]
[[File:Networking_rutos_manual_modbus_modbus_tcp_server.png|border|class=tlt-border]]


<table class="nd-mantable">
<table class="nd-mantable">
Line 30: Line 45:
     <tr>
     <tr>
       <td>Enable</td>
       <td>Enable</td>
       <td>yes | no; default: <b>none</b></td>
       <td>off | on; default: <b>off</b></td>
       <td>Turns Modbus TCP on or off.</td>
       <td>Turns Modbus TCP on or off.</td>
     </tr>
     </tr>
     <tr>
     <tr>
       <td>Port</td>
       <td>Port</td>
       <td>integer [0..65535]; default: '''502'''</td>
       <td>integer [0..65535]; default: <b>502</b></td>
       <td>TCP port used for Modbus communications.</td>
       <td>TCP port used for Modbus communications.</td>
     </tr>
     </tr>
Line 41: Line 56:
       <td>Device ID</td>
       <td>Device ID</td>
       <td>integer [0..255]; default: <b>1</b></td>
       <td>integer [0..255]; default: <b>1</b></td>
       <td>The device's Modbus slave ID. When set to 0, it will respond to requests addressed to any ID.</td>
       <td>The device's Modbus server ID. When set to 0, it will respond to requests addressed to any ID.</td>
    </tr>
    <tr>
    <td>Mobile Data type</td>
        <td>Bytes | Kilobytes | Megabytes; default: <b>Bytes</b></td>
        <td>Selects mobile data unit representation type.</td>
     </tr>
     </tr>
     <tr>
     <tr>
     <td>Allow Remote Access</td>
     <td>Allow remote access</td>
         <td>yes | no; default: <b>no</b></td>
         <td>off | on; default: <b>off</b></td>
         <td>Allows remote Modbus connections by adding an exception to the device's firewall on the port specified in the field above.</td>
         <td>Allows remote Modbus connections by adding an exception to the device's firewall on the port specified in the field above.</td>
     </tr>
     </tr>
     <tr>
     <tr>
     <td>Keep persistent connection</td>
     <td>Keep persistent connection</td>
         <td>yes | no; default: <b>no</b></td>
         <td>off | on; default: <b>onn</b></td>
         <td>Allows keep the connection open after responding a Modbus TCP master request.</td>
         <td>Allows keep the connection open after responding a Modbus TCP client request.</td>
     </tr>
     </tr>
     <tr>
     <tr>
     <td>Connection timeout</td>
     <td>Connection timeout</td>
         <td> integer; default: <b>0</b></td>
         <td>integer [0..60]; default: <b>0</b></td>
         <td> Sets TCP timeout in seconds after which the connection is forcefully closed.</td>
         <td>Sets TCP timeout in seconds after which the connection is forcefully closed.</td>
    </tr>
    <tr>
    <td>Enable custom register block</td>
        <td>off | <span style="color:blue">on</span>; default: <b>off</b></td>
        <td>Allows the usage of custom register block.</td>
    </tr>
    <tr>
    <td><span style="color:blue">Register file path</span></td>
        <td>path; default: <b>/tmp/regfile</b></td>
        <td>Path to file in which the custom register block will be stored. Files inside /tmp or /var are stored in RAM. They vanish after reboot, but do not degrade flash memory. Files elsewhere are stored in flash memory. They remain after reboot, but degrade flash memory (severely, if operations are frequent).</td>
    </tr>
    <tr>
    <td><span style="color:blue">First register number</span></td>
        <td>integer [1025..65536]; default: <b>1025</b></td>
        <td>First register in custom register block</td>
    </tr>
    <tr>
    <td><span style="color:blue">Register count</span></td>
        <td>integer [1..64512]; default: <b>128</b></td>
        <td>Register count in custom register block </td>
    </tr>
</table>
 
{{#ifeq: {{{serial}}} | 1 |
==Modbus Serial Server==
A <b>Modbus Serial Server</b> listens for connections from a serial client and sends out a response or sets some system related parameter in accordance with the given query. This provides the user with the possibility to set or get system parameters.
 
===Modbus Serial Server Configuration===
----
The <b>Modbus Serial Server Configuration</b> section is used to configure serial servers. By default, the list is empty. To add a new server instance, enter the instance name, select serial interface and click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_server_add_button_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}_v1.png|border|class=tlt-border]]
 
After clicking 'Add' you will be redirected to the newly added server instance configuration page.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_server_configuration_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}_v1.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enable</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables this Modbus Serial Server instance configuration.</td>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>none</b></td>
        <td>Name of the serial server instance. Used for management purposes only.</td>
    </tr>
    <tr>
        <td>Device</td>
        <td>{{Template: Networking rutos manual serial ports| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}; default: <b>{{Template: Networking rutos manual default serial port| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}</b></td>
        <td>Specifies which serial port will be used for serial communication.</td>
    </tr>
    <tr>
        <td>Device ID</td>
        <td>integer [0..255]; default: <b>1</b></td>
        <td>Specifies which serial port will be used for serial communication.</td>
    </tr>
    <tr>
        <td>Baud rate</td>
        <td>300 {{!}} 1200 {{!}} 2400 {{!}} 4800 {{!}} 9600 {{!}} 19200 {{!}} 38400 {{!}} 57600 {{!}} 115200{{#ifeq: {{{rs485}}} | 1 | {{!}} 230400 {{!}} 460800 {{!}} 921600 {{!}} 1000000 {{!}} 3000000|}}; default: <b>9600</b></td>
        <td>Serial data transmission rate (in bits per second).</td>
    </tr>
    <tr>
        <td>Data bits</td>
        <td>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|{{#switch:{{{series}}}|TRB2|TRB2M=|#default=5 {{!}} 6 {{!}}}} 7 {{!}} |}}8; default: <b>8</b></td>
        <td>Number of data bits for each character.</td>
    </tr>
    <tr>
        <td>Stop bits</td>
        <td>1{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} 2|}}; default: <b>1</b></td>
        <td>Stop bits sent at the end of every character allow the receiving signal hardware to detect the end of a character and to resynchronise with the character stream. Electronic devices usually use one stop bit. Two stop bits are required if slow electromechanical devices are used.</td>
     </tr>
     </tr>
    <tr>
        <td>Parity</td>
        <td>Even {{!}} Odd{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} Mark {{!}} Space|}} {{!}} None; default: <b>None</b></td>
        <td>In serial transmission, parity is a method of detecting errors. An extra data bit is sent with each data character, arranged so that the number of 1 bits in each character, including the parity bit, is always odd or always even. If a byte is received with the wrong number of 1s, then it must have been corrupted. However, an even number of errors can pass the parity check.
            <ul>
                <li><b>None</b> (<b>N</b>) - no parity method is used.</li>
                <li><b>Odd</b> (<b>O</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be odd.</li>
                <li><b>Even</b> (<b>E</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be even.</li>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<li><b>Space</b> (<b>s</b>) - the parity bit will always be a binary 0.</li>
                <li><b>Mark</b> (<b>M</b>) - the parity bit will always be a binary 1.</li>|}}
            </ul>
        </td>
    </tr>
    <tr>
        <td>Flow control</td>
        <td>None {{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} RTS/CTS {{!}} Xon/Xoff|}}; default: <b>None</b></td>
        <td>In many circumstances a transmitter might be able to send data faster than the receiver is able to process it. To cope with this, serial lines often incorporate a "handshaking" method, usually distinguished between hardware and software handshaking.
{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<ul>
                <li><b>RTS/CTS</b> - hardware handshaking. RTS and CTS are turned OFF and ON from alternate ends to control data flow, for instance when a buffer is almost full.</li>
                <li><b>Xon/Xoff</b> - software handshaking. The Xon and Xoff characters are sent by the receiver to the sender to control when the sender will send data, i.e., these characters go in the opposite direction to the data being sent. The circuit starts in the "sending allowed" state. When the receiver's buffers approach capacity, the receiver sends the Xoff character to tell the sender to stop sending data. Later, after the receiver has emptied its buffers, it sends an Xon character to tell the sender to resume transmission.</li>
            </ul>|}}
        </td>
    </tr>{{#ifeq: {{{rs485}}} | 1 |
    <tr>
        <td><span style="color:blue">RS485:</span> Full Duplex</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables RS485 full duplex.</td>
    </tr>|}}
     <tr>
     <tr>
     <td>Enable custom register block</td>
     <td>Enable custom register block</td>
         <td>yes | no; default: <b>no</b></td>
         <td>off {{!}} <span style="color:blue">on</span>; default: <b>off</b></td>
         <td>Allow custom register block.</td>
        <td>Allows the usage of custom register block.</td>
    </tr>
    <tr>
    <td><span style="color:blue">Register file path</span></td>
        <td>path; default: <b>/tmp/regfile</b></td>
        <td>Path to file in which the custom register block will be stored. Files inside /tmp or /var are stored in RAM. They vanish after reboot, but do not degrade flash memory. Files elsewhere are stored in flash memory. They remain after reboot, but degrade flash memory (severely, if operations are frequent).</td>
    </tr>
    <tr>
    <td><span style="color:blue">First register number</span></td>
        <td>integer [1025..65536]; default: <b>1025</b></td>
         <td>First register in custom register block</td>
    </tr>
    <tr>
    <td><span style="color:blue">Register count</span></td>
        <td>integer [1..64512]; default: <b>128</b></td>
        <td>Path to file in which the custom register block will be stored. Files inside /tmp or /var are stored in RAM. They vanish after reboot, but do not degrade flash memory. Files elsewhere are stored in flash memory. They remain after reboot, but degrade flash memory (severely, if operations are frequent).</td>
     </tr>
     </tr>
</table>
</table>


==Modbus TCP Master==
|}}


A Modbus <b>master</b> device can request data from Modbus slaves. The Modbus TCP Master section is used to configure Modbus TCP slaves.
==Modbus Registers==
 
{{Template:Networking_rutos_manual_modbus_modbus_tcp_get_parameters_table
|mobile = {{{mobile}}}
|series = {{{series}}}
|name = {{{name}}}
|analog = {{{analog}}}
|gps = {{{gps}}}
|dualsim = {{{dualsim}}}
}}
 
{{Template:Networking_rutos_manual_modbus_modbus_tcp_set_parameters_table
|wifi = {{{wifi}}}
|mobile = {{{mobile}}}
|series = {{{series}}}
|name = {{{name}}}
|dualsim = {{{dualsim}}}
}}
==Modbus TCP Client==


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_v1.png|border|class=tlt-border]]
A <b>Modbus Client</b> device can request data from Modbus servers. The Modbus TCP Client section is used to configure Modbus TCP servers and enable Client. By default, the server list is empty and client is disabled. To add a new server, click the 'Add' button


To add a new slave, simply click the 'Add' button.
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_modbus_tcp_server_devices_add_button_v2.png|border|class=tlt-border]]


You can create a maximum of 10 slave configurations.
After clicking 'Add' you will be redirected to the newly added server's configuration page.


===Slave device configuration===
===Server Device Configuration===
----
----
The figure below is an example of the <b>Slave device configuration</b> and the table below provides information on the fields contained in that section:
The <b>Server Device Configuration</b> section is used to configure the parameters of Modbus TCP servers that the Client (this {{{name}}} device) will be querying with requests. The figure below is an example of the Server Device Configuration and the table below provides information on the fields contained in that section:


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_slave_configuration_v1.png|border|class=tlt-border]]
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_server_device_configuration.png|border|class=tlt-border]]


<table class="nd-mantable">
<table class="nd-mantable">
Line 90: Line 247:
         <td>Enabled</td>
         <td>Enabled</td>
         <td>off | on; default: <b>off</b></td>
         <td>off | on; default: <b>off</b></td>
         <td>Turns communication with the slave device on or off.</td>
         <td>Turns communication with the server device on or off.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Name</td>
         <td>Name</td>
         <td>string; default: <b>none</b></td>
         <td>string; default: <b>none</b></td>
         <td>Slave device's name, used for easier management purposes.</td>
         <td>Server device's name, used for easier management purposes.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Slave ID</td>
         <td>Server ID</td>
         <td>integer [0..255]; default: <b>none</b></td>
         <td>integer [0..255]; default: <b>none</b></td>
         <td>Slave ID. Each slave in a network is assigned a unique identifier ranging from 1 to 255. When the master requests data from a slave, the first byte it sends is the Slave ID. When set to 0, the slave will respond to requests addressed to any ID.</td>
         <td>Server ID. Each server in a network is assigned a unique identifier ranging from 1 to 255. When the client requests data from a server, the first byte it sends is the Server ID. When set to 0, the server will respond to requests addressed to any ID.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>IP address</td>
         <td>IP address</td>
         <td>ip; default: <b>none</b></td>
         <td>ip4; default: <b>none</b></td>
         <td>Slave device's IP address.</td>
         <td>Server device's IP address.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Port</td>
         <td>Port</td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>Slave device's Modbus TCP port.</td>
         <td>Server device's Modbus TCP port.</td>
    </tr>
    <tr>
        <td>Period</td>
        <td>integer [1..86400]; default: <b>60</b></td>
        <td>Interval at which requests are sent to the slave device.</td>
     </tr>
     </tr>
     <tr>
     <tr>
Line 121: Line 273:
         <td>integer [1..30]; default: '''5'''</td>
         <td>integer [1..30]; default: '''5'''</td>
         <td>Maximum response wait time.</td>
         <td>Maximum response wait time.</td>
    </tr>
    <tr>
        <td>Always reconnect</td>
        <td>off | on; default: <b>off</b></td>
        <td>Create new connection after every Modbus request.</td>
    </tr>
    <tr>
        <td>Number of timeouts</td>
        <td>integer [0..10]; default: <b>1</b></td>
        <td>Skip pending request and reset connection after number of request failures.</td>
    </tr>
    <tr>
        <td>Frequency</td>
        <td>Period {{!}} Schedule; default: <b>Period</b></td>
        <td></td>
    </tr>
    <tr>
        <td>Delay</td>
        <td>integer [0..999]; default: <b>0</b></td>
        <td>Wait in milliseconds after connection initialization.</td>
    </tr>
    <tr>
        <td>Period</td>
        <td>integer [1..99999]; default: <b>none</b></td>
        <td>Interval in seconds for sending requests to this device</td>
     </tr>
     </tr>
</table>
</table>


===Requests configuration===
===Requests Configuration===
----
----
A Modbus <b>request</b> is a way of obtaining data from Modbus slaves. The master sends a request to a slave specifying the function code to be performed. The slave then sends the requested data back to the Modbus master. You can create a maximum of 64 request configurations for each slave device.
A Modbus <b>request</b> is a way of obtaining data from Modbus servers. The client sends a request to a server specifying the function code to be performed. The server then sends the requested data back to the Modbus client.
 
<span style="color:red"> <b>Note: </b></span> Modbus TCP Client uses <i>Register Number</i> instead of <i>Register Address</i> for pointing to a register. For example, to request the <i>Uptime</i> of a device, you must use <b>2</b> in the <i>First Register</i> field.


The figure below is an example of the Requests configuration section and the table below provides information contained in the fields of that section:
The Request Configuration list is empty by default. To add a new Request Configuration loon to the Add New Instance section. Enter a custom name into the 'Name' field and click the 'Add' button:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_requests_configuration_add_new_instance.png|border|class=tlt-border]]
 
The new Request Configuration should become visible in the list:


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_v1.png|border|class=tlt-border]]
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_v1.png|border|class=tlt-border]]
Line 141: Line 324:
         <td>Name</td>
         <td>Name</td>
         <td>string; default: <b>Unnamed</b></td>
         <td>string; default: <b>Unnamed</b></td>
         <td>Request name. Used for easier management purposes.</td>
         <td>Name of this Request Configuration. Used for easier management purposes.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Data type</td>
         <td>Data type</td>
         <td>8bit INT | 8bit UINT | 16bit INT, high byte first | 16bit INT, low byte first | 16bit UINT, high byte first | 16bit UINT, low byte first | 32bit float, Byte order 1,2,3,4 | 32bit float, Byte order 4,3,2,1 | 32bit float, Byte order 2,1,4,3 | 32bit float, Byte order 3,4,1,2; default: <b>16bit INT, high byte first</b></td>
         <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool {{!}} PDU; default: <b>16bit INT, high byte first</b></td>
         <td>How read data will be stored.</td>
         <td>Defines how read data will be stored.</td>
     </tr>
     </tr>
     <tr>
     <tr>
Line 165: Line 348:
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Enabled</td>
         <td>Remove Brackets</td>
        <td>off | on; default: <b>off</b></td>
        <td>Removes the starting and ending brackets from the request (only for read requests).</td>
    </tr>
    <tr>
        <td>off/on slider</td>
         <td>off | on; default: <b>off</b></td>
         <td>off | on; default: <b>off</b></td>
         <td>Turns the request on or off.</td>
         <td>Turns the request on or off.</td>
Line 174: Line 362:
         <td>Deletes the request.</td>
         <td>Deletes the request.</td>
     </tr>
     </tr>
</table>


</table>
<b>Additional note:</b> by default the newly added Request Configurations are turned off. You can use the on/off slider to the right of the Request Configuration to turn it on:


After having configured a request, you should see a new 'Testing' section appear. It is used to check whether the configuration works correctly. Simply press the 'Test' button and a response should appear in the box below.
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_requests_configuration_on_off_slider.png|border|class=tlt-border]]
----
After having configured a request, you should see a new 'Request Configuration Testing' section appear. It is used to check whether the configuration works correctly. Simply click the 'Test' button and a response should appear in the box below. <b>Note:</b> to use test buttons, you need to enable [[#Modbus_TCP_Client|Client section]]. A successful response to a test may look something like this:


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_testing_v1.png|border|class=tlt-border]]
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_testing.png|border|class=tlt-border]]


===Alarms Configuration===
===Alarms Configuration===
----
----
<b>Alarms</b> are a way of setting up automated actions when some Modbus values meet user specified conditions. The figure below is an example of the Alarms Configuration list.
<b>Alarms</b> are a way of setting up automated actions when some Modbus values meet user-defined conditions. When the Modbus TCP Client (this {{{name}}} device) requests some information from a server device it compares that data to with the parameters set in an Alarm Configuration. If the comparison meets the specified condition (more than, less than, equal to, not equal to), the Client performs a user-specified action, for example, a Modbus write request or switching the state of an output.


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_alarms_configuration_v1.png|border|class=tlt-border]]
The figure below is an example of the Alarms Configuration list. To create a new Alarm, click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_alarms_configuration_add_button_v2.png|border|class=tlt-border]]


It is empty by default. So, to begin editing click the 'Add' button and you should be redirected to a page such as this:
After adding the Alarm you should be redirected to its configuration page which should look similar to this:


[[File:Networking_rutos_manual_modbus_modbus_tcp_master_alarms_configuration_alarm_configuration_v1.png|border|class=tlt-border]]
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_alarms_configuration_v1.png|border|class=tlt-border]]


<table class="nd-mantable">
<table class="nd-mantable">
Line 205: Line 398:
         <td>Function code</td>
         <td>Function code</td>
         <td>Read Coil Status (1) | Read Input Status (2) | Read Holding Registers (3) | Read Input Registers (4); default: <b>Read Coil Status (1)</b></td>
         <td>Read Coil Status (1) | Read Input Status (2) | Read Holding Registers (3) | Read Input Registers (4); default: <b>Read Coil Status (1)</b></td>
         <td>Modbus function used for this alarm's Modbus request.</td>
         <td>Modbus function used for this alarm's Modbus request. The Modbus TCP Client (this {{{name}}} device) perform this request as often as specified in the 'Period' field in [[#Server_Device_Configuration|Server Device Configuration]].</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Register</td>
         <td>Compared condition data type</td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>16bit INT, high byte first</b></td>
        <td>Select data type that will be used for checking conditions.</td>
    </tr>
    <tr>
        <td>First register number</td>
         <td>integer [1..65536]; default: <b>none</b></td>
         <td>integer [1..65536]; default: <b>none</b></td>
         <td>Number of the Modbus coil/input/holding-register/input-register to read from.</td>
         <td>Number of the Modbus coil/input/holding-register/input-register to read from.</td>
    </tr>
    <tr>
        <td>Values</td>
        <td>various; default: <b>none</b></td>
        <td>The value against which the read data will be compared.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Condition</td>
         <td>Condition</td>
         <td>More than | Less than | Equal to | Not Equal to; default: <b>Equal to</b></td>
         <td>More than | Less than | Equal to | Not Equal to | Less or equal | More or equal; default: <b>More than</b></td>
         <td>When a value is obtained it will be compared against the value specified in the following field. The comparison will be made in accordance with the condition specified in this field.</td>
         <td>When a value is obtained it will be compared against the value specified in the following field. The comparison will be made in accordance with the condition specified in this field.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Value</td>
         <td>Action frequency</td>
        <td>Every trigger | First trigger; default: <b>Every trigger</b></td>
        <td>Describes how frequently the specified action will be taken.</td>
    </tr>
    <tr>
        <td>Redundancy protection</td>
        <td>off | <span style="color:blue">on</span>; default: <b>off</b></td>
        <td>Protection against executing a configured action too often.</td>
    </tr>
    <tr>
        <td><span style="color:blue">Redundancy protection period</span></td>
        <td>integer [1..86400]; default: <b>none</b></td>
        <td>Duration to activate redundancy protection for, measured in seconds. This field becomes visible only when 'Redundancy protection' is turned on.</td>
    </tr>
    <tr>
        <td>Action</td>
        <td>Ubus event {{!}} {{#ifeq:{{{mobile}}}|1|<span style="color: #0054a6;">SMS</span> {{!}}|}} <span style="color: purple;">MODBUS Write Request</span>{{#switch:{{{series}}}|TCR1|TRB2|TRB2M=|#default= {{!}} Trigger output}} | <span style="color: red;">MQTT message</span>; default: <b>MODBUS Write Request</b></td>
        <td>Action that will be taken if the condition is met. Possible actions:
            <ul>{{#ifeq: {{{mobile}}} | 1 |
                <li><b>SMS</b> - sends and SMS message to a specified recipient(s).</li>|}}
                <li><b>Modbus Request</b> - sends a Modbus Write request to a specified server.</li>
{{#switch:{{{series}}}|TCR1|TRB2|TRB2M=|#default=<li><b>Trigger output</b> - changes state of selected I/O output pin.</li>}}
            </ul>
        </td>
    </tr>{{#ifeq: {{{mobile}}} | 1 |
    <tr>
        <td><span style="color: #0054a6;">SMS: Message</span></td>
        <td>string; default: <b>none</b></td>
        <td>SMS message text.</td>
    </tr>
    <tr>
        <td><span style="color: #0054a6;">SMS: Phone number</span></td>
        <td>phone number; default: <b>none</b></td>
        <td>Recipient's phone number.</td>
    </tr>|}}
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: IP address</span></td>
        <td>ip | host; default: <b>none</b></td>
        <td>Modbus server's IP address.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Port</span></td>
        <td>integer [0..65535]; default: <b>none</b></td>
        <td>Modbus server's port.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Timeout</span></td>
        <td>integer [1..30]; default: <b>5</b></td>
        <td>Maximum time to wait for a response.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: ID</span></td>
        <td>integer [1..255]; default: <b>none</b></td>
        <td>Modbus server ID.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Modbus function</span></td>
        <td>Set Single Coil (5) | Set Single Register (6) | Set Multiple Coils (15) | Set Multiple Registers (16); default: <b>Set Single Coil (5)</b></td>
        <td>A function code specifies the type of register being addressed by a Modbus request.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Executed action data type</span></td>
        <td>8bit INT | 8bit UINT | 16bit INT, high byte first | 16bit INT, low byte first | 16bit UINT, high byte first | 16bit UINT, low byte first | 32bit float (various Byte order) | 32bit INT (various Byte order) | 32bit UNIT (various Byte order) | ASCII | Hex | Bool; default: <b>Bool</b></td>
        <td>Select data type that will be used for executing action.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: First register number</span></td>
        <td>integer [0..65535]; default: <b>none</b></td>
        <td>Begins reading from the register specified in this field.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Values</span></td>
        <td>integer [0..65535]; default: <b>none</b></td>
        <td>Register/Coil values to be written (multiple values must be separated by space character).</td>
    </tr>{{#switch:{{{series}}}|TCR1|TRB2|TRB2M=|#default=
    <tr>
        <td><span style="color: green;">Trigger output: Output</span></td>{{#switch:{{{series}}}
| RUTX|RUT2 =<td>4PIN output; default: <b>4PIN output</b></td>
| TRB1|RUT3 =<td>Configurable Input/Output (3) {{!}} Configurable Input/Output (4); default: <b>Configurable Input/Output (3)</b></td>
| RUT9 =<td>Open collector output {{!}} Relay output {{!}} 4PIN output; default: <b>Open collector output</b></td>}}
        <td>Selects which output will be triggered.</td>
    </tr>
    <tr>
        <td><span style="color: green;">Trigger output: I/O Action</span></td>
        <td>Turn On {{!}} Turn Off {{!}} Invert; default: <b>Turn On</b></td>
        <td>Selects the action performed on the output.</td>
    </tr>}}
    <tr>
        <td><span style="color: red;">MQTT message: JSON format</span></td>
        <td>string; default: <b>none</b> </td>
        <td>Below this field you can find special codes that begin with the '%' sign. Each code represents a piece information related to the status of the device. Include these codes in the field for dynamic information reports. Possible values: Local time, Unix time, Router name, Device name, Serial number, Current FW version, LAN IP address, Monitoring status, UTC time in ISO, WAN IP address, New line, Modbus server ID, Modbus server IP, First register number, Register value, Mobile IP addresses, Signal strength, Operator name, Network type, Data connection state, Network state, IMSI, IMEI, Modem model, Modem serial number, SIM pin state, SIM state, RSCP, ECIO, RSRP, SINR, RSRQ, ICCID, CELLID, Neighbour cells, Network info, Network serving, WAN MAC address, Analog Current Loop (6,9), Analog Input (6,9), Input (3), Digital Input (1), Output (4), Isolated Output (3,4,8), Isolated Input (2,7), Relay (5,10)
        </td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Hostname</span></td>
        <td>host | ip; default: <b>none</b> </td>
        <td>Broker’s IP address or hostname.</td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Port</span></td>
        <td>integer [0..65535]; default: <b>1883</b></td>
        <td>Broker's port number.</td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Keepalive</span></td>
        <td>positive integer; default: <b>none</b></td>
        <td>The number of seconds after which the broker should send a PING message to the client if no other messages have been exchanged in that time</td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Topic</span></td>
        <td>string; default: <b>none</b></td>
        <td>The name of the topic that the broker will subscribe to.</td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Client ID</span></td>
        <td>positive integer; default: <b>none</b></td>
        <td>Client ID to send with the data. If empty, a random client ID will be generated </td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: QoS</span></td>
        <td>At most once (0) | At least once (1) | Exactly once (2); default: <b>At most once (0)</b></td>
        <td>A period of time (in seconds) which has to pass after a trigger event before this Action is executed.</td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Use root CA</span></td>
        <td>off | on; default: <b>off</b></td>
        <td>Use root CA for verifying the servers certificates </td>
    </tr>
    <tr>
        <td><span style="color: red;">MQTT message: Use TLS</span></td>
        <td>off | on; default: <b>off</b></td>
        <td>Turns the use of TLS/SSL for this MQTT connection on or off.</td>
    </tr><tr>
        <td><span style="color: red;">MQTT message: Use credentials</span></td>
        <td>off | on; default: <b>off</b></td>
        <td>Turns the use of username and password for this MQTT connection on or off.</td>
    </tr>
</table>
{{#ifeq: {{{serial}}} | 1 |
==Modbus Serial Client==
 
The <b>Modbus Serial Client</b> page is used to configure the device as a Modbus RTU Client. Modbus RTU (remote terminal unit) is a serial communication protocol mainly used in communication via serial interfaces.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_client_v2.png|border|class=tlt-border]]
<!--<u><b>Note:</b> Modbus Serial Client is additional software that can be installed from the <b>System → [[{{{name}}} Package Manager|Package Manager]]</b> page.</u>-->
 
===Modbus Serial Device Configuration===
----
This section is used to create Modbus Serial Client's server device instances. You may create a Serial Device instance for each supported serial interface.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_master_device_configuration.png|border|class=tlt-border]]
 
By default there are no instances created. To add a new serial device configuration, enter an instance name and click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_master_device_configuration_add_button_{{#ifexpr:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|0}}.png|border|class=tlt-border]]
 
After clicking 'Add' you will be redirected to the newly added device's configuration page.
 
====RS Device Modbus Client Configuration====
----
This section is used to configure the Modbus Serial Client's server device interface settings.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_client_device_configuration_rs_device_modbus_client_configuration_v1_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enable</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables this Modbus Serial Device instance configuration.</td>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>none</b></td>
        <td>Name of the serial device instance. Used for management purposes only.</td>
    </tr>
    <tr>
        <td>Device</td>
        <td>{{Template: Networking rutos manual serial ports| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}; default: <b>{{Template: Networking rutos manual default serial port| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}</b></td>
        <td>Specifies which serial port will be used for serial communication.</td>
    </tr>
    <tr>
        <td>Baud rate</td>
        <td>300 {{!}} 1200 {{!}} 2400 {{!}} 4800 {{!}} 9600 {{!}} 19200 {{!}} 38400 {{!}} 57600 {{!}} 115200{{#ifeq: {{{rs485}}} | 1 | {{!}} 230400 {{!}} 460800 {{!}} 921600 {{!}} 1000000 {{!}} 3000000|}}; default: <b>9600</b></td>
        <td>Serial data transmission rate (in bits per second).</td>
    </tr>
    <tr>
        <td>Data bits</td>
        <td>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|{{#switch:{{{series}}}|TRB2|TRB2M=|#default=5 {{!}} 6 {{!}}}} 7 {{!}} |}}8; default: <b>8</b></td>
        <td>Number of data bits for each character.</td>
    </tr>
    <tr>
        <td>Stop bits</td>
        <td>1{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} 2|}}; default: <b>1</b></td>
        <td>Stop bits sent at the end of every character allow the receiving signal hardware to detect the end of a character and to resynchronise with the character stream. Electronic devices usually use one stop bit. Two stop bits are required if slow electromechanical devices are used.</td>
    </tr>
    <tr>
        <td>Parity</td>
        <td>Even {{!}} Odd{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} Mark {{!}} Space|}} {{!}} None; default: <b>None</b></td>
        <td>In serial transmission, parity is a method of detecting errors. An extra data bit is sent with each data character, arranged so that the number of 1 bits in each character, including the parity bit, is always odd or always even. If a byte is received with the wrong number of 1s, then it must have been corrupted. However, an even number of errors can pass the parity check.
            <ul>
                <li><b>None</b> (<b>N</b>) - no parity method is used.</li>
                <li><b>Odd</b> (<b>O</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be odd.</li>
                <li><b>Even</b> (<b>E</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be even.</li>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<li><b>Space</b> (<b>s</b>) - the parity bit will always be a binary 0.</li>
                <li><b>Mark</b> (<b>M</b>) - the parity bit will always be a binary 1.</li>|}}
            </ul>
        </td>
    </tr>
    <tr>
        <td>Flow control</td>
        <td>None {{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} RTS/CTS {{!}} Xon/Xoff|}}; default: <b>None</b></td>
        <td>In many circumstances a transmitter might be able to send data faster than the receiver is able to process it. To cope with this, serial lines often incorporate a "handshaking" method, usually distinguished between hardware and software handshaking.
{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<ul>
                <li><b>RTS/CTS</b> - hardware handshaking. RTS and CTS are turned OFF and ON from alternate ends to control data flow, for instance when a buffer is almost full.</li>
                <li><b>Xon/Xoff</b> - software handshaking. The Xon and Xoff characters are sent by the receiver to the sender to control when the sender will send data, i.e., these characters go in the opposite direction to the data being sent. The circuit starts in the "sending allowed" state. When the receiver's buffers approach capacity, the receiver sends the Xoff character to tell the sender to stop sending data. Later, after the receiver has emptied its buffers, it sends an Xon character to tell the sender to resume transmission.</li>
            </ul>|}}
        </td>
    </tr>{{#ifeq: {{{rs485}}} | 1 |
    <tr>
        <td><span style="color:blue">RS485:</span> Full Duplex</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables RS485 full duplex.</td>
    </tr>|}}
</table>
 
===Modbus Server Device Configuration===
----
This section is used to create server instances that the Client (this {{{name}}} device) will be querying with requests.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_client_modbus_server_device_configuration.png|border|class=tlt-border]]
 
By default there are no instances created. To add a new server configuration, enter an instance name, select a serial device instance and click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_client_modbus_server_device_configuration_add_button.png|border|class=tlt-border]]
 
After clicking 'Add' you will be redirected to the newly added server's configuration page.
 
====Server Device Configuration====
----
The <b>Server Device Configuration</b> section is used to configure the parameters of Modbus RTU servers that the Client (this {{{name}}} device) will be querying with requests. The figure below is an example of the Server Device Configuration and the table below provides information on the fields contained in that section:
 
[[File:Networking_rutos_manual_modbus_modbus_serial_client_server_device_configuration.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enabled</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns communication with the server device on or off.</td>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>none</b></td>
        <td>Server device's name, used for easier management purposes.</td>
    </tr>
    <tr>
        <td>Serial device</td>
        <td><i>serial device instance</i>; default: <b>none</b></td>
        <td>Specifies which serial device will be used on this server.</td>
    </tr>
    <tr>
        <td>Server ID</td>
        <td>integer [0..255]; default: <b>1</b></td>
        <td>Server ID. Each server in a network is assigned a unique identifier ranging from 1 to 255. When the client requests data from a server, the first byte it sends is the Server ID. When set to 0, the server will respond to requests addressed to any ID.</td>
    </tr>
    <tr>
        <td>Number of timeouts</td>
        <td>integer [0..10]; default: <b>0</b></td>
        <td>Skip pending request and reset connection after number of request failures.</td>
    </tr>
    <tr>
        <td>Frequency</td>
        <td>Period {{!}} Schedule; default: <b>Period</b></td>
        <td></td>
    </tr>
    <tr>
        <td>Period</td>
        <td>integer [1..99999]; default: <b>none</b></td>
        <td>Interval at which requests are sent to the server device.</td>
    </tr>
    <tr>
        <td>Timeout</td>
        <td>integer [1..60]; default: <b>1</b></td>
        <td>Maximum response wait time.</td>
    </tr>
</table>
 
=====Requests Configuration=====
----
A Modbus <b>request</b> is a way of obtaining data from Modbus servers. The client sends a request to a servers specifying the function code to be performed. The server then sends the requested data back to the Modbus client.
 
<span style="color:red"> <b>Note: </b></span> Modbus Serial Client uses <i>Register Number</i> instead of <i>Register Address</i> for pointing to a register. For example, to request the <i>Uptime</i> of a device, you must use <b>2</b> in the <i>First Register</i> field.
 
The Request Configuration list is empty by default. To add a new Request Configuration loon to the Add New Instance section. Enter a custom name into the 'Name' field and click the 'Add' button:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_requests_configuration_add_new_instance.png|border|class=tlt-border]]
 
The new Request Configuration should become visible in the list:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_v1.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>Unnamed</b></td>
        <td>Name of this Request Configuration. Used for easier management purposes.</td>
    </tr>
    <tr>
        <td>Data type</td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool {{!}} PDU; default: <b>16bit INT, high byte first</b></td>
        <td>Defines how read data will be stored.</td>
    </tr>
    <tr>
        <td>Function</td>
        <td>Read coils (1) {{!}} Read input coils (2) {{!}} Read holding registers (3) {{!}} Read input registers (4) {{!}} Set single coil (5) {{!}} Set single coil register (6) {{!}} Set multiple coils (15) {{!}} Set multiple holding registers (16); default: <b>Read holding registers (3)</b></td>
        <td>Specifies the type of register being addressed by a Modbus request.
        </td>
    </tr>
    <tr>
        <td>First Register</td>
        <td>integer [0..65535]; default: <b>1</b></td>
        <td>First Modbus register from which data will be read.</td>
    </tr>
    <tr>
        <td>Register Count / Values</td>
        <td>integer [1..2000]; default: <b>1</b></td>
        <td>Number of Modbus registers that will be read during the request.</td>
    </tr>
    <tr>
        <td>Remove Brackets</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Removes the starting and ending brackets from the request (only for read requests).</td>
    </tr>
    <tr>
        <td>off/on slider</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns the request on or off.</td>
    </tr>
    <tr>
        <td>Delete [ X ]</td>
        <td>- (interactive button)</td>
        <td>Deletes the request.</td>
    </tr>
</table>
 
<b>Additional note:</b> by default the newly added Request Configurations are turned off. You can use the on/off slider to the right of the Request Configuration to turn it on:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_requests_configuration_on_off_slider.png|border|class=tlt-border]]
----
After having configured a request, you should see a new 'Request Configuration Testing' section appear. It is used to check whether the configuration works correctly. Simply click the 'Test' button and a response should appear in the box below. <b>Note:</b> to use test buttons, you need to enable [[#Modbus_Serial_Client|Client section]]. A successful response to a test may look something like this:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_testing.png|border|class=tlt-border]]
 
=====Modbus Client Alarms=====
----
<b>Alarms</b> are a way of setting up automated actions when some Modbus values meet user-defined conditions. When the Modbus Serial Client (this {{{name}}} device) requests some information from a server device it compares that data to with the parameters set in an Alarm Configuration. If the comparison meets the specified condition (more than, less than, equal to, not equal to), the Client performs a user-specified action, for example, a Modbus write request or switching the state of an output.
 
The figure below is an example of the Modbus Client Alarms list. To create a new Alarm, click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_client_alarms_configuration_add_button.png|border|class=tlt-border]]
 
After this you should be redirected to that Alarm's configuration page which should look similar to this:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_alarms_configuration_v1.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enabled</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns the alarm on or off.</td>
    </tr>
    <tr>
        <td>Function code</td>
        <td>Read Coil Status (1) {{!}} Read Input Status (2) {{!}} Read Holding Registers (3) {{!}} Read Input Registers (4); default: <b>Read Coil Status (1)</b></td>
        <td>Modbus function used for this alarm's Modbus request. The Modbus TCP Client (this {{{name}}} device) perform this request as often as specified in the 'Period' field in [[#Server_Device_Configuration|Server Device Configuration]].</td>
    </tr>
    <tr>
        <td>Compared condition data type</td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>16bit INT, high byte first</b></td>
        <td>Select data type that will be used for checking conditions.</td>
    </tr>
    <tr>
        <td>First register number</td>
        <td>integer [1..65536]; default: <b>none</b></td>
        <td>Number of the Modbus coil/input/holding-register/input-register to read from.</td>
    </tr>
    <tr>
        <td>Values</td>
         <td>various; default: <b>none</b></td>
         <td>various; default: <b>none</b></td>
         <td>The value against which the read data will be compared.</td>
         <td>The value against which the read data will be compared.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Value</td>
         <td>Condition</td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>More than {{!}} Less than {{!}} Equal to {{!}} Not Equal to {{!}} Less or equal {{!}} More or equal; default: <b>More than</b></td>
         <td>The value against which the read data will be compared.</td>
         <td>When a value is obtained it will be compared against the value specified in the following field. The comparison will be made in accordance with the condition specified in this field.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Action frequency</td>
         <td>Action frequency</td>
         <td>Every trigger | First trigger; default: <b>Every trigger</b></td>
         <td>Every trigger {{!}} First trigger; default: <b>Every trigger</b></td>
         <td>Describes how frequently the specified action will be taken.</td>
         <td>Describes how frequently the specified action will be taken.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Redundancy protection</td>
         <td>Redundancy protection</td>
         <td>off | on; default: <b>off</b></td>
         <td>off {{!}} <span style="color:blue">on</span>; default: <b>off</b></td>
         <td>Protection against executing a configured action too often.</td>
         <td>Protection against executing a configured action too often.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Redundancy protection period</td>
         <td><span style="color:blue">Redundancy protection period</span></td>
         <td>integer [1..86400]; default: <b>none</b></td>
         <td>integer [1..86400]; default: <b>none</b></td>
         <td>Duration to activate redundancy protection for, measured in seconds. This field becomes visible only when 'Redundancy protection' is turned on.</td>
         <td>Duration to activate redundancy protection for, measured in seconds. This field becomes visible only when 'Redundancy protection' is turned on.</td>
Line 244: Line 852:
     <tr>
     <tr>
         <td>Action</td>
         <td>Action</td>
         <td>SMS | MODBUS Write Request; default: <b>MODBUS Write Request</b></td>
         <td>{{#ifeq:{{{mobile}}}|1|SMS {{!}}|}} MODBUS Write Request{{#switch:{{{series}}}|TCR1|TRB2|TRB2M=|#default= {{!}} Trigger output}}; default: <b>MODBUS Write Request</b></td>
         <td>Action that will be taken if the condition is met. Possible actions:
         <td>Action that will be taken if the condition is met. Possible actions:
             <ul>
             <ul>{{#ifeq: {{{mobile}}} | 1 |
                 <li><b>SMS</b> - sends and SMS message to a specified recipient(s).</li>
                 <li><b>SMS</b> - sends and SMS message to a specified recipient(s).</li>|}}
                 <li><b>Modbus Request</b> - sends a Modbus Write request to a specified slave.</li>
                 <li><b>Modbus Request</b> - sends a Modbus Write request to a specified server.</li>
{{#switch:{{{series}}}|TCR1|TRB2|TRB2M|#default=<li><b>Trigger output</b> - changes state of selected I/O output pin.</li>}}
             </ul>
             </ul>
         </td>
         </td>
     </tr>
     </tr>{{#ifeq: {{{mobile}}} | 1 |
     <tr>
     <tr>
         <td><span style="color: #0054a6;">SMS: Message</span></td>
         <td><span style="color: #0054a6;">SMS: Message</span></td>
Line 261: Line 870:
         <td>phone number; default: <b>none</b></td>
         <td>phone number; default: <b>none</b></td>
         <td>Recipient's phone number.</td>
         <td>Recipient's phone number.</td>
    </tr>|}}
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Timeout</span></td>
        <td>integer [1..30]; default: <b>5</b></td>
        <td>Maximum time to wait for a response.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: ID</span></td>
        <td>integer [1..255]; default: <b>none</b></td>
        <td>Modbus server ID.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td><span style="color: purple;">MODBUS Write Request: IP address</span></td>
         <td><span style="color: purple;">MODBUS Write Request: Modbus function</span></td>
         <td>ip | host; default: <b>none</b></td>
        <td>Read Single Coil (5) {{!}} Set Single Register (6) {{!}} Set Multiple Coils (15) {{!}} Set Multiple Registers (16); default: <b>Set Single Coil (5)</b></td>
         <td>Modbus slave's IP address.</td>
        <td>A function code specifies the type of register being addressed by a Modbus request.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: Executed action data type</span></td>
         <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UNIT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>Bool</b></td>
        <td>Select data type that will be used for executing action.</td>
    </tr>
    <tr>
        <td><span style="color: purple;">MODBUS Write Request: First register number</span></td>
        <td>integer [0..65535]; default: <b>none</b></td>
         <td>Begins reading from the register specified in this field.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td><span style="color: purple;">MODBUS Write Request: Port</span></td>
         <td><span style="color: purple;">MODBUS Write Request: Values</span></td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>Modbus slave's port.</td>
         <td>Register/Coil values to be written (multiple values must be separated by space character).</td>
    </tr>{{#switch:{{{series}}}|TCR1|TRB2|TRB2M=|#default=
    <tr>
        <td><span style="color: green;">Trigger output: Output</span></td>{{#switch:{{{series}}}
| RUTX|RUT2 =<td>4PIN output; default: <b>4PIN output</b></td>
| TRB1|RUT3 =<td>Configurable Input/Output (3) {{!}} Configurable Input/Output (4); default: <b>Configurable Input/Output (3)</b></td>
| RUT9 =<td>Open collector output {{!}} Relay output {{!}} 4PIN output; default: <b>Open collector output</b></td>}}
        <td>Selects which output will be triggered.</td>
    </tr>
    <tr>
        <td><span style="color: green;">Trigger output: I/O Action</span></td>
        <td>Turn On {{!}} Turn Off {{!}} Invert; default: <b>Turn On</b></td>
        <td>Selects the action performed on the output.</td>
    </tr>}}
</table>
|}}
{{#ifeq: {{{console}}} | 1 |
===Console===
----
This section is used to configure the Modbus Serial Client's <b>Console</b> serial interface settings. Refer to the figure and table below for information on Console configuration.
 
[[File:Networking_rutos_manual_modbus_modbus_serial_master_console_configuration.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enabled</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns Modbus Serial Client configuration via RS232 on or off. Both this and RS232 from Services → [[{{{name}}} RS232|RS232]] cannot be enabled at the same time.</td>
    </tr>
    <tr>
        <td>Baud rate</td>
        <td>300 {{!}} 1200 {{!}} 2400 {{!}} 4800 {{!}} 9600 {{!}} 19200 {{!}} 38400 {{!}} 57600 {{!}} 115200 {{!}} 1000000; default: <b>115200</b></td>
        <td>Serial data transmission rate (in bits per second).</td>
    </tr>
    <tr>
        <td>Data bits</td>
        <td>5 {{!}} 6 {{!}} 7 {{!}} 8; default: <b>8</b></td>
        <td>Number of data bits for each character.</td>
    </tr>
    <tr>
        <td>Parity</td>
        <td>None {{!}} Even {{!}} Odd; default: <b>None</b></td>
        <td>In serial transmission, parity is a method of detecting errors. An extra data bit is sent with each data character, arranged so that the number of 1 bits in each character, including the parity bit, is always odd or always even. If a byte is received with the wrong number of 1s, then it must have been corrupted. However, an even number of errors can pass the parity check.
            <ul>
                <li><b>None</b> (<b>N</b>) - no parity method is used.</li>
                <li><b>Odd</b> (<b>O</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be odd.</li>
                <li><b>Even</b> (<b>E</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be even.</li>
            </ul>
        </td>
    </tr>
    <tr>
        <td>Stop bits</td>
        <td>1 {{!}} 2; default: <b>1</b></td>
        <td>Stop bits sent at the end of every character allow the receiving signal hardware to detect the end of a character and to resynchronise with the character stream. Electronic devices usually use one stop bit. Two stop bits are required if slow electromechanical devices are used.</td>
     </tr>
     </tr>
    <tr>
        <td>Flow control</td>
        <td>None {{!}} RTS/CTS {{!}} Xon/Xoff; default: <b>None</b></td>
        <td>In many circumstances a transmitter might be able to send data faster than the receiver is able to process it. To cope with this, serial lines often incorporate a "handshaking" method, usually distinguished between hardware and software handshaking.
            <ul>
                <li><b>RTS/CTS</b> - hardware handshaking. RTS and CTS are turned OFF and ON from alternate ends to control data flow, for instance when a buffer is almost full.</li>
                <li><b>Xon/Xoff</b> - software handshaking. The Xon and Xoff characters are sent by the receiver to the sender to control when the sender will send data, i.e., these characters go in the opposite direction to the data being sent. The circuit starts in the "sending allowed" state. When the receiver's buffers approach capacity, the receiver sends the Xoff character to tell the sender to stop sending data. Later, after the receiver has emptied its buffers, it sends an Xon character to tell the sender to resume transmission.</li>
            </ul>
        </td>
    </tr>
</table>
====Console Server Devices List====
----
The <b>Console Server Devices List</b> section is used to configure the parameters of Modbus RTU servers that the Client (this {{{name}}} device) will be querying with requests.
The list is empty by default. In order to create a new server device configuration, click the 'Add' button. A new configuration window should pop up.
[[File:Networking_rutos_manual_modbus_modbus_serial_master_console_slave_devices_list_add_button.png|border|class=tlt-border]]
=====Server Device Configuration=====
----
The <b>Server Device Configuration</b> section is used to configure the parameters of Modbus RTU servers that the Client (this {{{name}}} device) will be querying with requests. The figure below is an example of the Server Device Configuration and the table below provides information on the fields contained in that section:
[[File:Networking_rutos_manual_modbus_modbus_serial_master_rs232_slave_device_configuration.png|border|class=tlt-border]]
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enabled</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns communication with the server device on or off.</td>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>none</b></td>
        <td>Server device's name, used for easier management purposes.</td>
    </tr>
    <tr>
        <td>Server ID</td>
        <td>integer [0..255]; default: <b>none</b></td>
        <td>Server ID. Each server in a network is assigned a unique identifier ranging from 1 to 255. When the client requests data from a server, the first byte it sends is the Server ID. When set to 0, the server will respond to requests addressed to any ID.</td>
    </tr>
    <tr>
        <td>Period</td>
        <td>integer [1..86400]; default: <b>60</b></td>
        <td>Interval at which requests are sent to the server device.</td>
    </tr>
    <tr>
        <td>Timeout</td>
        <td>integer [1..30]; default: <b>5</b></td>
        <td>Maximum response wait time.</td>
    </tr>
</table>
=====Requests Configuration=====
----
A Modbus <b>request</b> is a way of obtaining data from Modbus servers. The client sends a request to a server specifying the function code to be performed. The server then sends the requested data back to the Modbus client.
<span style="color:red"> <b>Note: </b></span> Modbus Serial Client uses <i>Register Number</i> instead of <i>Register Address</i> for pointing to a register. For example, to request the <i>Uptime</i> of a device, you must use <b>2</b> in the <i>First Register</i> field.
The Request Configuration list is empty by default. To add a new Request Configuration loon to the Add New Instance section. Enter a custom name into the 'Name' field and click the 'Add' button:
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_add_new_instance.png|border|class=tlt-border]]
The new Request Configuration should become visible in the list:
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_v1.png|border|class=tlt-border]]
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>Unnamed</b></td>
        <td>Name of this Request Configuration. Used for easier management purposes.</td>
    </tr>
    <tr>
        <td>Data type</td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>16bit INT, high byte first</b></td>
        <td>Defines how read data will be stored.</td>
    </tr>
    <tr>
        <td>Function</td>
        <td>Read coils (1) {{!}} Read input coils (2) {{!}} Read holding registers (3) {{!}} Read input registers (4) {{!}} Set single coil (5) {{!}} Set single coil register (6) {{!}} Set multiple coils (15) {{!}} Set multiple holding registers (16); default: <b>Read holding registers (3)</b></td>
        <td>Specifies the type of register being addressed by a Modbus request.
        </td>
    </tr>
    <tr>
        <td>First Register</td>
        <td>integer [0..65535]; default: <b>1</b></td>
        <td>First Modbus register from which data will be read.</td>
    </tr>
    <tr>
        <td>Register Count / Values</td>
        <td>integer [1..2000]; default: <b>1</b></td>
        <td>Number of Modbus registers that will be read during the request.</td>
    </tr>
    <tr>
        <td>Remove Brackets</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Removes the starting and ending brackets from the request (only for read requests).</td>
    </tr>
    <tr>
        <td>off/on slider</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns the request on or off.</td>
    </tr>
    <tr>
        <td>Delete [ X ]</td>
        <td>- (interactive button)</td>
        <td>Deletes the request.</td>
    </tr>
</table>
<b>Additional note:</b> by default the newly added Request Configurations are turned off. You can use the on/off slider to the right of the Request Configuration to turn it on:
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_on_off_slider.png|border|class=tlt-border]]
----
After having configured a request, you should see a new 'Request Configuration Testing' section appear. It is used to check whether the configuration works correctly. Simply click the 'Test' button and a response should appear in the box below. A successful response to a test may look something like this:
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_requests_configuration_testing.png|border|class=tlt-border]]
=====Modbus Client Alarms=====
----
<b>Alarms</b> are a way of setting up automated actions when some Modbus values meet user-defined conditions. When the Modbus Serial Client (this {{{name}}} device) requests some information from a server device it compares that data to with the parameters set in an Alarm Configuration. If the comparison meets the specified condition (more than, less than, equal to, not equal to), the Client performs a user-specified action, for example, a Modbus write request or switching the state of an output.
The figure below is an example of the Modbus Client Alarms list. To create a new Alarm, click the 'Add' button.
[[File:Networking_rutos_manual_modbus_modbus_serial_master_modbus_master_alarms_add_button.png|border|class=tlt-border]]
After this you should be redirected to that Alarm's configuration page which should look similar to this:
[[File:Networking_rutos_manual_modbus_modbus_tcp_master_alarms_configuration_v1.png|border|class=tlt-border]]
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enabled</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns the alarm on or off.</td>
    </tr>
    <tr>
        <td>Function code</td>
        <td>Read Coil Status (1) {{!}} Read Input Status (2) {{!}} Read Holding Registers (3) {{!}} Read Input Registers (4); default: <b>Read Coil Status (1)</b></td>
        <td>Modbus function used for this alarm's Modbus request. The Modbus TCP Client (this {{{name}}} device) perform this request as often as specified in the 'Period' field in [[#Server_Device_Configuration|Server Device Configuration]].</td>
    </tr>
    <tr>
        <td>Compared condition data type</td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UINT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>16bit INT, high byte first</b></td>
        <td>Select data type that will be used for checking conditions.</td>
    </tr>
    <tr>
        <td>First register number</td>
        <td>integer [1..65536]; default: <b>none</b></td>
        <td>Number of the Modbus coil/input/holding-register/input-register to read from.</td>
    </tr>
    <tr>
        <td>Values</td>
        <td>various; default: <b>none</b></td>
        <td>The value against which the read data will be compared.</td>
    </tr>
    <tr>
        <td>Condition</td>
        <td>More than {{!}} Less than {{!}} Equal to {{!}} Not Equal to {{!}} Less or equal {{!}} More or equal; default: <b>More than</b></td>
        <td>When a value is obtained it will be compared against the value specified in the following field. The comparison will be made in accordance with the condition specified in this field.</td>
    </tr>
    <tr>
        <td>Action frequency</td>
        <td>Every trigger {{!}} First trigger; default: <b>Every trigger</b></td>
        <td>Describes how frequently the specified action will be taken.</td>
    </tr>
    <tr>
        <td>Redundancy protection</td>
        <td>off {{!}} <span style="color:blue">on</span>; default: <b>off</b></td>
        <td>Protection against executing a configured action too often.</td>
    </tr>
    <tr>
        <td><span style="color:blue">Redundancy protection period</span></td>
        <td>integer [1..86400]; default: <b>none</b></td>
        <td>Duration to activate redundancy protection for, measured in seconds. This field becomes visible only when 'Redundancy protection' is turned on.</td>
    </tr>
    <tr>
        <td>Action</td>
        <td>{{#ifeq:{{{mobile}}}|1|SMS {{!}}|}} MODBUS Write Request; default: <b>MODBUS Write Request</b></td>
        <td>Action that will be taken if the condition is met. Possible actions:
            <ul>{{#ifeq: {{{mobile}}} | 1 |
                <li><b>SMS</b> - sends and SMS message to a specified recipient(s).</li>|}}
                <li><b>Modbus Request</b> - sends a Modbus Write request to a specified server.</li>
            </ul>
        </td>
    </tr>{{#ifeq: {{{mobile}}} | 1 |
    <tr>
        <td><span style="color: #0054a6;">SMS: Message</span></td>
        <td>string; default: <b>none</b></td>
        <td>SMS message text.</td>
    </tr>
    <tr>
        <td><span style="color: #0054a6;">SMS: Phone number</span></td>
        <td>phone number; default: <b>none</b></td>
        <td>Recipient's phone number.</td>
    </tr>|}}
     <tr>
     <tr>
         <td><span style="color: purple;">MODBUS Write Request: Timeout</span></td>
         <td><span style="color: purple;">MODBUS Write Request: Timeout</span></td>
Line 280: Line 1,179:
         <td><span style="color: purple;">MODBUS Write Request: ID</span></td>
         <td><span style="color: purple;">MODBUS Write Request: ID</span></td>
         <td>integer [1..255]; default: <b>none</b></td>
         <td>integer [1..255]; default: <b>none</b></td>
         <td>Modbus slave ID.</td>
         <td>Modbus server ID.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td><span style="color: purple;">MODBUS Write Request: Modbus function</span></td>
         <td><span style="color: purple;">MODBUS Write Request: Modbus function</span></td>
         <td>Read Force Single Coil (5) | Preset Single Register (6) | Force Multiple Coils (15) | Force Multiple Registers (16); default: <b>Force Single Coil (5)</b></td>
         <td>Read Single Coil (5) {{!}} Set Single Register (6) {{!}} Set Multiple Coils (15) {{!}} Set Multiple Registers (16); default: <b>Set Single Coil (5)</b></td>
         <td>A function code specifies the type of register being addressed by a Modbus request.</td>
         <td>A function code specifies the type of register being addressed by a Modbus request.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td><span style="color: purple;">MODBUS Write Request: First register</span></td>
        <td><span style="color: purple;">MODBUS Write Request: Executed action data type</span></td>
        <td>8bit INT {{!}} 8bit UINT {{!}} 16bit INT, high byte first {{!}} 16bit INT, low byte first {{!}} 16bit UINT, high byte first {{!}} 16bit UINT, low byte first {{!}} 32bit float (various Byte order) {{!}} 32bit INT (various Byte order) {{!}} 32bit UNIT (various Byte order) {{!}} ASCII {{!}} Hex {{!}} Bool; default: <b>Bool</b></td>
        <td>Select data type that will be used for executing action.</td>
    </tr>
    <tr>
         <td><span style="color: purple;">MODBUS Write Request: First register number</span></td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>integer [0..65535]; default: <b>none</b></td>
         <td>Begins reading from the register specified in this field.</td>
         <td>Begins reading from the register specified in this field.</td>
Line 298: Line 1,202:
     </tr>
     </tr>
</table>
</table>
{{#ifeq: {{{series}}} | RUTX ||
|}}
==MQTT Gateway==


The <b>MQTT Gateway</b> function is used to transfer Modbus data over MQTT. Refer to the table for information on MQTT gateway configuration fields.
==MQTT Modbus Gateway==
 
The <b>MQTT Modbus Gateway</b> function is used to transfer Modbus data (send requests, receive responses) over MQTT. When it is enabled, the device (this {{{name}}}) subscribes to a REQUEST topic and publishes on a RESPONSE topic on a specified MQTT broker. It translates received MQTT message payload to a Modbus request and relays it to the specified Modbus TCP server.
 
When the MQTT Gateway receives a response from the server, it translates it to an MQTT message and publishes it on the RESPONSE topic.
 
[[File:Networking_rutos_manual_modbus_mqtt_gateway_scheme.png]]
 
Below is an example of the MQTT Gateway page. Refer to the table for information on MQTT Gateway configuration fields.


[[File:Networking_rutos_manual_modbus_mqtt_gateway_v1.png|border|class=tlt-border]]
[[File:Networking_rutos_manual_modbus_mqtt_gateway_v1.png|border|class=tlt-border]]
Line 313: Line 1,224:
     <tr>
     <tr>
         <td>Enable</td>
         <td>Enable</td>
         <td>off <nowiki>|</nowiki> on; default: <b>off</b></td>
         <td>off {{!}} on; default: <b>off</b></td>
         <td>Turns MQTT gateway on or off.</td>
         <td>Turns MQTT gateway on or off.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Host</td>
         <td>Host</td>
         <td>ip <nowiki>|</nowiki> host; default: <b>127.0.0.1</b></td>
         <td>ip {{!}} host; default: <b>127.0.0.1</b></td>
         <td>IP address or hostname of an MQTT broker.</td>
         <td>IP address or hostname of an MQTT broker.</td>
     </tr>
     </tr>
Line 329: Line 1,240:
         <td>Request topic</td>
         <td>Request topic</td>
         <td>alphanumeric string; default: <b>request</b></td>
         <td>alphanumeric string; default: <b>request</b></td>
         <td>.</td>
         <td>MQTT topic for sending requests.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Response topic</td>
         <td>Response topic</td>
         <td>alphanumeric string; default: <b>response</b></td>
         <td>alphanumeric string; default: <b>response</b></td>
         <td>.</td>
         <td>MQTT topic for subscribing to responses.</td>
    </tr>
    <tr>
        <td>QoS</td>
        <td>At most once (0) {{!}} At least once (1) {{!}} Exactly once (2); default: <b>Exactly once (2)</b></td>
        <td>Specifies quality of service.</td>
     </tr>
     </tr>
     <tr>
     <tr>
Line 346: Line 1,262:
         <td>Password for authentication to the MQTT broker.</td>
         <td>Password for authentication to the MQTT broker.</td>
     </tr>
     </tr>
</table>|}}
    <tr>
==See also==
        <td>Client ID</td>
        <td>integer; default: <b>none</b></td>
        <td>Specifies client ID for MQTT broker.</td>
    </tr>
    <tr>
        <td>Keepalive</td>
        <td>integer; default: <b>5</b></td>
        <td>Keepalive message to MQTT broker (seconds)</td>
    </tr>
    <tr>
        <td>Use TLS/SSL</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns TLS support on or off</td>
    </tr>
    <tr>
        <td>TLS type</td>
        <td><span style="color:blue">cert</span> {{!}} <span style="color:red">psk</span>; default: <b>cert</b></td>
        <td>Selects the type of TLS encryption</td>
    </tr>
    <tr>
        <td>TLS insecure</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Disables TLS security</td>
    </tr>
    <tr>
        <td><span style="color:blue">Certificate files from device</span></td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Choose this option if you want to use certificate files generated on device.</td>
    </tr>
    <tr>
        <td><span style="color:blue">CA file</span></td>
        <td>string; default: <b>none</b></td>
        <td>Upload/select certificate authority file.</td>
    </tr>
    <tr>
        <td><span style="color:blue">Certificates file</span></td>
        <td>string; default: <b>none</b></td>
        <td>Upload/select certificate file.</td>
    </tr>
    <tr>
        <td><span style="color:blue">Key file</span></td>
        <td>string; default: <b>none</b></td>
        <td>Upload/select certificate key file.</td>
    </tr>
    <tr>
        <td><span style="color:red">PSK</span></td>
        <td>string; default: <b>none</b></td>
        <td>Specifies the pre-shared key.</td>
    </tr>
    <tr>
        <td><span style="color:red">Identity</span></td>
        <td>string; default: <b>none</b></td>
        <td>Specifies identity.</td>
    </tr>
</table>
{{#ifeq:{{{serial}}}|1|
===Serial Gateway Configuration===
----
<b>Serial Gateway Configuration</b> section displays Serial gateway instances currently existing on the router.
 
By default the list is empty. To create a new gateway instance, enter the ID of serial device, select serial interface and click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_mqtt_gateway_serial_gateway_configuration_add_button_v1_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}.png|border|class=tlt-border]]
 
After this you should be redirected to instance's configuration page which should look similar to this:
 
[[File:Networking_rutos_manual_modbus_mqtt_gateway_serial_gateway_configuration_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}_v1.png|border|class=tlt-border]]
 
<table class="nd-mantable">
    <tr>
        <th>Field</th>
        <th>Value</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enable</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables this Serial Gateway instance configuration.</td>
    </tr>
    <tr>
        <td>Name</td>
        <td>string; default: <b>none</b></td>
        <td>Name of the gateway instance. Used for management purposes only.</td>
    </tr>
    <tr>
        <td>Device</td>
        <td>{{Template: Networking rutos manual serial ports| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}; default: <b>{{Template: Networking rutos manual default serial port| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}</b></td>
        <td>Specifies which serial port will be used for serial communication.</td>
    </tr>
    <tr>
        <td>Baud rate</td>
        <td>300 {{!}} 1200 {{!}} 2400 {{!}} 4800 {{!}} 9600 {{!}} 19200 {{!}} 38400 {{!}} 57600 {{!}} 115200{{#ifeq: {{{rs485}}} | 1 | {{!}} 230400 {{!}} 460800 {{!}} 921600 {{!}} 1000000 {{!}} 3000000|}}; default: <b>9600</b></td>
        <td>Serial data transmission rate (in bits per second).</td>
    </tr>
    <tr>
        <td>Data bits</td>
        <td>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|{{#switch:{{{series}}}|TRB2|TRB2M=|#default=5 {{!}} 6 {{!}}}} 7 {{!}} |}}8; default: <b>8</b></td>
        <td>Number of data bits for each character.</td>
    </tr>
    <tr>
        <td>Stop bits</td>
        <td>1{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} 2|}}; default: <b>1</b></td>
        <td>Stop bits sent at the end of every character allow the receiving signal hardware to detect the end of a character and to resynchronise with the character stream. Electronic devices usually use one stop bit. Two stop bits are required if slow electromechanical devices are used.</td>
    </tr>
    <tr>
        <td>Parity</td>
        <td>Even {{!}} Odd{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} Mark {{!}} Space|}} {{!}} None; default: <b>None</b></td>
        <td>In serial transmission, parity is a method of detecting errors. An extra data bit is sent with each data character, arranged so that the number of 1 bits in each character, including the parity bit, is always odd or always even. If a byte is received with the wrong number of 1s, then it must have been corrupted. However, an even number of errors can pass the parity check.
            <ul>
                <li><b>None</b> (<b>N</b>) - no parity method is used.</li>
                <li><b>Odd</b> (<b>O</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be odd.</li>
                <li><b>Even</b> (<b>E</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be even.</li>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<li><b>Space</b> (<b>s</b>) - the parity bit will always be a binary 0.</li>
                <li><b>Mark</b> (<b>M</b>) - the parity bit will always be a binary 1.</li>|}}
            </ul>
        </td>
    </tr>
    <tr>
        <td>Flow control</td>
        <td>None {{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} RTS/CTS {{!}} Xon/Xoff|}}; default: <b>None</b></td>
        <td>In many circumstances a transmitter might be able to send data faster than the receiver is able to process it. To cope with this, serial lines often incorporate a "handshaking" method, usually distinguished between hardware and software handshaking.
{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<ul>
                <li><b>RTS/CTS</b> - hardware handshaking. RTS and CTS are turned OFF and ON from alternate ends to control data flow, for instance when a buffer is almost full.</li>
                <li><b>Xon/Xoff</b> - software handshaking. The Xon and Xoff characters are sent by the receiver to the sender to control when the sender will send data, i.e., these characters go in the opposite direction to the data being sent. The circuit starts in the "sending allowed" state. When the receiver's buffers approach capacity, the receiver sends the Xoff character to tell the sender to stop sending data. Later, after the receiver has emptied its buffers, it sends an Xon character to tell the sender to resume transmission.</li>
            </ul>|}}
        </td>
    </tr>{{#ifeq: {{{rs485}}} | 1 |
    <tr>
        <td><span style="color:blue">RS485:</span> Full Duplex</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables RS485 full duplex.</td>
    </tr>|}}
</table>
|}}
===Request messages===
----
<span style="color:red"> <b>Note: </b></span>MQTT Gateway uses <i>Register Number</i> instead of <i>Register Address</i> for pointing to a register. For example, to request the <i>Uptime</i> of a device, you must use <b>2</b> in the <i>Register Number</i> field.
 
Modbus request data sent in the MQTT payload should be generated in accordance with the one of the following formats:


{{Template: Networking_device_modbus_see_also}}
* TCP:
  <b>0 <COOKIE> <IP_TYPE> <IP> <PORT> <TIMEOUT> <SERVER_ID> <MODBUS_FUNCTION> <FIRST_REGISTER> <REGISTER_COUNT/VALUES></b>
* Serial:
  <b>1 <COOKIE> <SERIAL_DEVICE_ID> <TIMEOUT> <SERVER_ID> <MODBUS_FUNCTION> <FIRST_REGISTER> <REGISTER_COUNT/VALUES></b>
* MODBUS TCP connection management messages:
  <b>2 <COOKIE> <CONNECTION_INDEX> <ACTION></b><br>
  <b>2 <COOKIE> <CONNECTION_INDEX> 0 <IP_TYPE> <IP> <PORT> <TIMEOUT></b>


[[Category:{{{name}}} Services section]]
Explanation:
<!--


<ul>
    <li><b>Cookie</b> - a 64-bit unsigned integer in range [0..2<sup>64</sup>-1]). A cookie is used in order to distinguish which response belongs to which request, each request and the corresponding response contain a matching cookie: a 64-bit unsigned integer.</li>
    <li><b>IP type</b> - host IP address type. Possible values:
        <ul>
            <li><b>0</b> - IPv4 address;</li>
            <li><b>1</b> - IPv6 address;</li>
            <li><b>2</b> - hostname that will be resolved to an IP address.</li>
        </ul>
    </li>
    <li><b>IP</b> - IP address of a Modbus TCP server. IPv6 must be presented in full form (e.g., <i>2001:0db8:0000:0000:0000:8a2e:0370:7334</i>).</li>
    <li><b>Port</b> - port number of the Modbus TCP server.</li>
    <li><b>Timeout</b> - timeout for Modbus connection, in seconds. Range [1..999].</li>
    <li><b>Server ID</b> - Modbus TCP server ID. Range [1..255].</li>
    <li><b>Modbus function</b> - Modbus task type that will be executed. Possible values are:
        <ul>
            <li><b>1</b> - read coils;</li>
            <li><b>2</b> - read input coils;</li>
            <li><b>3</b> - read holding registers;</li>
            <li><b>4</b> - read input registers;</li>
            <li><b>5</b> - set single coil;</li>
            <li><b>6</b> - write to a single holding register;</li>
            <li><b>15</b> - set multiple coils;</li>
            <li><b>16</b> - write to multiple holding registers.</li>
        </ul>
    </li>
    <li><b>First register</b> - number (not address) of the first register/coil/input (in range [1..65536]) from which the registers/coils/inputs will be read/written to.</li>
    <li><b>Register count/value</b> - this value depends on the Modbus function:
        <ul>
            <li><b>1</b> - <u>coil count</u> (in range [1..2000]); must not exceed the boundary (first coil number + coil count <= 65537);</li>
            <li><b>2</b> - <u>input count</u> (in range [1..2000]); must not exceed the boundary (first input number + input count <= 65537);</li>
            <li><b>3</b> - <u>holding register count</u> (in range [0..125]); must not exceed the boundary (first register number + holding register count <= 65537);</li>
            <li><b>4</b> - <u>input register count</u> (in range [0..125]); must not exceed the boundary (first register number + input register count <= 65537);</li>
            <li><b>5</b> - <u>coil value</u> (in range [0..1]);</li>
            <li><b>6</b> - <u>holding register value</u> (in range [0..65535]);</li>
            <li><b>15</b> - <u>coil count</u> (in range [1..1968]); must not exceed the boundary (first coil number + coil count <= 65537); and <u>coil values</u> separated with commas, without spaces (e.g., <i>1,2,3,654,21,789</i>); there must be exactly as many values as specified (with coil count); each value must be in the range of [0..1].</li>
            <li><b>16</b> - <u>register count</u> (in range [1..123]); must not exceed the boundary (first register number + register count <= 65537); and <u>register values</u> separated with commas, without spaces (e.g., <i>1,2,3,654,21,789</i>); there must be exactly as many values as specified (with register count); each value must be in the range of [0..65535].</li>
        </ul>
    </li>
    <li><b>Serial device ID</b> - a string used to identify a serial device. Must match with <u>Device ID</u> field in MQTT Gateway page Serial gateway configuration section.</li>
    <li><b>Connection index</b> - a number used to identify a connection on which an action will be preformed (in range [0..7]).</li>
    <li><b>Action</b> - a connection action. Possible values are:
        <ul>
            <li><b>0</b> - OPEN. This will open a closed connection, reopen an already open connection with the same parameters or close an already open connection and open a new one with new parameters.</li>
            <li><b>1</b> - CLOSE. This will close an open connection and do nothing to the closed one.</li>
            <li><b>2</b> - STATUS. This will respond with either <b>OK 1</b> for an open connection or <b>OK 0</b> for a closed connection.</li>
        </ul>
    </li>
    <!-- <li><b>Timeout count</b> - number of timeouts. (in range []) </li> -->
</ul>


===Response messages===
----
A special response message can take one of the following forms:


<COOKIE> OK                              - <i>for functions 6 and 16</i>
<COOKIE> OK <VALUE> <VALUE> <VALUE>...  - <i>for function 3, where <VALUE> <VALUE> <VALUE>... are read register values</i>
<COOKIE> ERROR: ...                      - <i>for failures, where ... is the error description</i>


===Examples===
----
Below are a few <b>examples</b> of controlling/monitoring the internal Modbus TCP Server on {{{name}}}.
----
<b>Reboot the device</b>


<ul>
    <li>Request:<br><pre>0 65432 0 192.168.1.1 502 5 1 6 206 1</pre></li>
    <li>Response:<br><pre>65432 OK</pre></li>
</ul>
----
<b>Retrieve uptime</b>


==Modbus Data to Server==
<ul>
    <li>Request:<br><pre>0 65432 0 192.168.1.1 502 5 1 3 2 2</pre></li>
    <li>Response:<br><pre>65432 OK 0 5590</pre></li>
</ul>
----
If you're using Eclipse Mosquitto (MQTT implementation used on {{{name}}}), Publish/Subscribe commands may look something like this:


The Modbus <b>Data to Server</b> function provides you with the possibility to set up senders that transfer data collected from Modbus slaves to remote servers. To add a new data sender, enter the server's address, specify the data sending period and click the "Add" button:
<b>Retrieve uptime</b>


[[File:Networking_rutx_manual_modbus_add_new_data_sender_v1.png]]
<ul>
    <li>Request:<br><pre>mosquitto_pub -h 192.168.1.1 -p 1883 -t request -m "0 65432 0 192.168.1.1 502 5 1 3 2 2"</pre></li>
    <li>Response:<br><pre>mosquitto_sub -h 192.168.1.1 -p 1883 -t response
65432 OK 0 5590</pre></li>
</ul>
{{#ifeq: {{{serial}}} | 1 |
==Modbus TCP over Serial Gateway==
The <b>Modbus TCP over Serial gateway</b> serial type allows redirecting TCP data coming to a specified port to an RTU specified by the Server ID. The Server ID can be specified by the user or be obtained directly from the Modbus header.


===Data sender configuration===
===Modbus TCP over Serial Gateway Configuration===
----
----
When you add a new data sender, you will be redirected to its configuration window. The figure below is an example of that window and the table below provides information on the fields that it contains:
<b>Modbus TCP over Serial Gateway Configuration</b> section displays gateway instances currently existing on the router.


[[File:Networking_rutx_manual_modbus_data_sender_configuration_v1.png]]
By default the list is empty. To create a new gateway instance, enter the name of instance, select serial interface and click the 'Add' button.
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_over_serial_gateway_add_button_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}_v1.png|border|class=tlt-border]]
 
After this you should be redirected to instance's configuration page which should look similar to this:
 
[[File:Networking_rutos_manual_modbus_modbus_tcp_over_serial_gateway_configuration_rs232_{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|1|0}}_v2.png|border|class=tlt-border]]


<table class="nd-mantable">
<table class="nd-mantable">
     <tr>
     <tr>
         <th>Enabled</th>
         <th>Field</th>
         <th>off | on; Default: <b>off</b></th>
         <th>Value</th>
         <th>Turns the data sender ON or OFF</th>
        <th>Description</th>
    </tr>
    <tr>
        <td>Enable</td>
        <td>off {{!}} on; default: <b>off</b></td>
         <td>Enables this Modbus TCP over Serial Gateway instance configuration.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Name</td>
         <td>Name</td>
         <td>string; Default: <b>none</b></td>
         <td>string; default: <b>none</b></td>
         <td>Data sender's name. used for easier management purposes</td>
         <td>Name of the gateway instance. Used for management purposes only.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Protocol</td>
         <td>Device</td>
         <td>HTTP; Default: <b>HTTP</b></td>
         <td>{{Template: Networking rutos manual serial ports| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}; default: <b>{{Template: Networking rutos manual default serial port| rs232={{{rs232}}}| rs485={{{rs485}}}| usb = {{{usb}}}}}</b></td>  
         <td>Data sending protocol</td>
         <td>Specifies which serial port will be used for serial communication.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>JSON format</td>
         <td>Baud rate</td>
         <td>json string; Default: <b>{"ID":"%i", "TS":"%t","ST":"%s","VR":"%a"}</b></td>
         <td>300 {{!}} 1200 {{!}} 2400 {{!}} 4800 {{!}} 9600 {{!}} 19200 {{!}} 38400 {{!}} 57600 {{!}} 115200{{#ifeq: {{{rs485}}} | 1 | {{!}} 230400 {{!}} 460800 {{!}} 921600 {{!}} 1000000 {{!}} 3000000|}}; default: <b>9600</b></td>
         <td>Provides the possibility to fully customize the JSON segment</td>
         <td>Serial data transmission rate (in bits per second).</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Segment count</td>
         <td>Data bits</td>
         <td>1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10; Default: <b>1</b></td>
         <td>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|{{#ifeq:{{{series}}}|TRB2|TRB2M=|#default=5 {{!}} 6 {{!}}}} 7 {{!}} |}}8; default: <b>8</b></td>
         <td>Max segment count in one JSON string sent to server</td>
         <td>Number of data bits for each character.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>URL</td>
         <td>Stop bits</td>
         <td>host | ip; Default: <b>none</b></td>
         <td>1{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} 2|}}; default: <b>1</b></td>
         <td>Address of the server to which the data will be sent.</td>
         <td>Stop bits sent at the end of every character allow the receiving signal hardware to detect the end of a character and to resynchronise with the character stream. Electronic devices usually use one stop bit. Two stop bits are required if slow electromechanical devices are used.</td>
     </tr>
     </tr>
     <tr>
     <tr>
         <td>Period</td>
         <td>Parity</td>
         <td>integer [1..6400]; Default: <b>60</b></td>
         <td>Even {{!}} Odd{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} Mark {{!}} Space|}} {{!}} None; default: <b>None</b></td>
         <td>Data sending frequency (in seconds)</td>
        <td>In serial transmission, parity is a method of detecting errors. An extra data bit is sent with each data character, arranged so that the number of 1 bits in each character, including the parity bit, is always odd or always even. If a byte is received with the wrong number of 1s, then it must have been corrupted. However, an even number of errors can pass the parity check.
            <ul>
                <li><b>None</b> (<b>N</b>) - no parity method is used.</li>
                <li><b>Odd</b> (<b>O</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be odd.</li>
                <li><b>Even</b> (<b>E</b>) - the parity bit is set so that the number of "logical ones (1s)" has to be even.</li>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<li><b>Space</b> (<b>s</b>) - the parity bit will always be a binary 0.</li>
                <li><b>Mark</b> (<b>M</b>) - the parity bit will always be a binary 1.</li>|}}
            </ul>
        </td>
    </tr>
    <tr>
        <td>Flow control</td>
        <td>None{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1| {{!}} RTS/CTS {{!}} Xon/Xoff|}}; default: <b>None</b></td>
         <td>In many circumstances a transmitter might be able to send data faster than the receiver is able to process it. To cope with this, serial lines often incorporate a "handshaking" method, usually distinguished between hardware and software handshaking.
{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|<ul>
                <li><b>RTS/CTS</b> - hardware handshaking. RTS and CTS are turned OFF and ON from alternate ends to control data flow, for instance when a buffer is almost full.</li>
                <li><b>Xon/Xoff</b> - software handshaking. The Xon and Xoff characters are sent by the receiver to the sender to control when the sender will send data, i.e., these characters go in the opposite direction to the data being sent. The circuit starts in the "sending allowed" state. When the receiver's buffers approach capacity, the receiver sends the Xoff character to tell the sender to stop sending data. Later, after the receiver has emptied its buffers, it sends an Xon character to tell the sender to resume transmission.</li>
            </ul>|}}
        </td>
    </tr>
    <tr>
      <td>Listening IP</td>
      <td>ip; default: <b>none</b></td>
      <td>IP address to listen for incoming connections. (<i>0.0.0.0</i>) value may be used to listen for incoming connections on any interface or IP address.</td>
    </tr>
    <tr>
      <td>Port</td>
      <td>integer [0..65535]; default: <b>none</b></td>
      <td>Port number to listen for incoming connections.</td>
     </tr>
     </tr>
     <tr>
     <tr>
        <td>Data filtering</td>
    <td>Server ID configuration type</td>
         <td>All data | By slave ID | By slave IP; Default: <b>All data</b></td>
         <td><span style="color: green;">User defined</span> {{!}} <span style="color: purple;">Obtained from TCP</span>; default: <b>User defined</b></td>
         <td>Which data this sender will transfer to the server</td>
         <td>Specifies whether server IDs are user defined or automatically obtained from TCP.</td>
     </tr>
     </tr>
     <tr>
     <tr>
        <td>Retry on fail</td>
    <td><span style="color: green;">Server ID</span></td>
         <td>off | on; Default: <b>no</b></td>
         <td><span style="color: green;">integer</span>; default: <b>none</span></td>
         <td>Specifies whether the data sender should retry failed attempts (Retry until successful)</td>
         <td>Specifies the server ID of range of permitted server IDs. The way this field is named and its function depends on the value of the ''Server ID configuration'' field. <br> A range of IDs can be specified by placing a hyphen (<i>-</i>) between two integer numbers. For example, if you permit server IDs in the range of 10 to 20, you would specify it as: <i>10-20</i><br>You can also specify multiple values that are not connected in a range using commas (<i>,</i>). For example, to specify 6, 50 and 100 as permitted server IDs, you would have to use: <i>6,50,100</i></td>
     </tr>
     </tr>
     <tr>
     <tr>
        <td>Custom header</td>
    <td><span style="color: purple;">Permitted server IDs</span></td>
         <td>string; Default: <b>no</b></td>
         <td><span style="color: purple;">range of integers</span>; default: <b>1-247</b></td>
         <td>Adds a custom header(s) to HTTP requests</td>
         <td>Read <i>Server ID</i> field description.</td>
     </tr>
     </tr>
    <tr>
    <td>CRC verification</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Checks if sent serial message is not disturbed.</td>
    </tr>{{#ifeq:{{#expr: {{{rs232}}} or {{{usb}}}}} |1|
    <tr>
    <td>Echo</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Turns RS232 echo on or off. RS232 echo is a loopback test usually used to check whether the RS232 cable is working properly.</td>
    </tr>|}}{{#ifeq: {{{rs485}}} | 1 |
    <tr>
        <td><span style="color:blue">RS485:</span> Full Duplex</td>
        <td>off {{!}} on; default: <b>off</b></td>
        <td>Enables RS485 full duplex.</td>
    </tr>|}}
</table>
</table>
-->
 
===IP Filter===
----
The <b>IP Filter</b> section is used for configuring which network is allowed to communicate with the device. You may add a new instance by selecting the Interface and pressing Add.
 
[[File:Networking_rutos_manual_console_ip_filter.png|border|class=tlt-border]]
 
Then enter the IP address and save.
 
[[File:Networking_rutos_manual_console_ip_filter_instance_v2.png|border|class=tlt-border]]
|}}
 
==See also==
 
<ul>
    <li><b>[[Monitoring via Modbus|Monitoring via Modbus]]</b> - detailed examples on how to use Modbus TCP</li>
</ul>
 
[[Category:{{{name}}} Services section]]