ModbusRTU Master
Modbus Data BOOLEAN
Description When the data obtained from the slave device is a boolean (Range= 0 to 1), the Modbus Data BOOLEAN should be used.
Availability
  • Available only in the dw2xx & dw2xx-v2 series products
  • Requires library: System & I/O
  • Requires: Modbus Master
  • Firmware versions 0x2007 and later
savvy-SFD Graphic modbusRegBoolean5
Graphic with Parameters modbusRegBoolean5

Parameters

Modbus Address Internal Parameter, Read-write, Analog (signed 16-bit integer)
1 to 247

The Modbus RTU address of the slave device on the EIA-485 network.
PDU Address Internal Parameter, Read-write, Analog (unsigned 16-bit integer)
0 to 65000

The register's offset (wire) address of the data in the slave device. Typically, one less than specified Modbus RTU Address (e.g., to poll the data at Holding Register 40108 set the Data Address to 107).
Please refer to the Modbus Documentation for more information.
Modbus Type Internal Parameter, Read-write, Enumerated (signed 16-bit integer)

The Modbus RTU function code to be used to communicate wThe Modbus RTU function code to be used to communicate with the slave device.

Supported Function Codes are:

  • FC1 - Read Coil Status
  • FC2 - Read Input Status
  • FC3 - Read Holding Registers
  • FC4 - Read Input Registers
  • FC5 - Force Single Coil
  • FC6 - Preset Single Holding Register
  • FC16 - Preset Multiple Holding Registers

Note:
Optidrive products only support FC6 for writes (FC16 is NOT supported).
Yaskawa products have a special Accept/Enter command appended to their write funcions. Use the special Holding Register (Yaskawa) function block for these products.

ith the slave device.

Supported Function Codes are:

  • FC1 - Read Coil Status
  • FC2 - Read Input Status
  • FC3 - Read Holding Registers
  • FC4 - Read Input Registers
  • FC5 - Force Single Coil
  • FC6 - Preset Single Holding Register
  • FC16 - Preset Multiple Holding Registers

0 = Holding Reg. (FC 3, FC 16)
1 = Holding Reg. (FC 3, FC 6)
2 = Holding Reg. (Yaskawa)
3 = Input Reg. (FC 4)
4 = Coil (FC 1, FC 5)
5 = Input Discrete (FC 2)
Value Input, Read-write, Boolean (signed 16-bit integer)

The register's offset (wire) address of the data in the slave device. Typically, one less than specified Modbus RTU Address (e.g., to poll the data at Holding Register 40108 set the Data Address to 107).
0 = Low (0)
1 = High (1)
Last Error Output, Read-write, Enumerated (signed 16-bit integer)

The result of the last poll of the associated register address in the slave. If an error occurs, the local Last Error code may be cleared by clicking on this parameter and using the Reset command.
-16 = Unexpected Response
-15 = Multiple Errors (parity, framing, overrun, or break)
-14 = Break Received
-13 = Overrun Error
-12 = Framing Error
-11 = Parity Error
-10 = Unknown Error
-9 = Unexpected Byte Count
-8 = Unexpected Length
-7 = Internal Error
-6 = Unexpected Function Code
-5 = CRC Failure
-4 = Unexpected Address
-3 = Runt Response
-2 = Timeout
-1 = No Comms Port Defined
0 = None
1 = Illegal Function
2 = Illegal Data Address
3 = Illegal Data Value
4 = Slave Device Failure
5 = Acknowledge
6 = Slave Device Busy
7 = Negative Acknowledge
8 = Memory Parity Error
33 = Data Out of Range
34 = Write Protected
35 = Write during Undervoltage
36 = Write during Parameter Processing
Enable Input, Read-write, Boolean (signed 16-bit integer)

Used to Enable/Disable the polling of the associated register address in the slave.
0 = Disable
1 = Enable
Priority Internal Parameter, Read-write, Enumerated (signed 16-bit integer)

This parameter determines how often the associated parameter is updated on the Modbus RTU comms link.

Generally, the round-robin polling scheduler prioritizes the parameters as follows:

ParameterUpdated
HighEach parameter is updated every polling cycle.
MediumOne Medium parameter is updated every polling cycle until the entire Medium polling list is traversed.
LowAfter the Medium list is traversed, one Low parameter is processed the next High cycle. Then, the Medium list is traversed again before updating the next Low parameter.

For example, for two High parameters (H1, H2), three Medium parameters (M1, M2, M3), and two Low parameters (L1, L2) the sequence would be.

H1, H2, M1, H1, H2, M2, H1, H2, M3, H1, H2, L1,
H1, H2, M1, H1, H2, M2, H1, H2, M3, H1, H2, L2


0 = Low
1 = Medium
2 = High