MODEL: R30NCIE1
R30NCIE1 SPECIFICATIONS
ES-9020 Rev.6 Page 5/7
https://www.m-system.co.jp/
MODULE STATUS, ERROR STATUS, DATA ERROR STATUS
0
15
Module 1
Module 2
Module 3
:
Module 16
Shows each module's availability and error status.
I/O DATA DESCRIPTIONS
■OPERATION IN CASE OF A COMMUNICATION ERROR WITH I/O MODULES
When the communication between the network module and the I/O modules is lost due to an error in an input module, the last
process values are held until the communication is re-established.
■ ANALOG DATA (16-bit data, models: R30SV4, R30SV2, R30YV4, R30YS4, R30US4, etc.)
0
15
16-bit binary data.
Basically, 0 to 100% of the selected I/O range is converted into 0 to 10000 (binary).
Negative percentage is represented in 2's complements.
■ ANALOG DATA (16-bit data, models: R30RS4, R30TS4, R30US4, etc.)
0
15
16-bit binary data.
With °C temperature unit, raw data is multiplied by 10. For example, 25.5°C is converted into 255.
With °F temperature unit, the integer section of raw data is directly converted into the data.
For example, 135.4°F is converted into 135.
Minus temperature is converted into negative values, represented in 2’s complements.
■ ANALOG DATA (16-bit data, models: R30CT4E etc.)
0
15
16-bit binary data.
Integer obtained by multiplying unit value (A) by 100.
In case of CLSE-R5, integer obtained by multiplying unit value (A) by 1000.
■ ANALOG DATA (32-bit data, models: R3-PA2, PA4A, WT1, WT4, etc.)
0
15
+0
0
15
Higher 16 bits
+1
32-bit binary data is used for accumulated counts, encoder positions and active energy.
Lower 16 bits are allocated from the lowest address to higher ones, higher 16 bits in turn.
Lower 16 bits
