Toshiba Power Supply RS485 User Manual

E6581315  
TOSVERT VF-AS1 Series  
RS485 Communication Function  
Instruction Manual  
Notice  
1. Make sure that this instruction manual is delivered to the end user of the inverter.  
2. Read this manual before first using the communications function, and keep it handy as a  
reference for maintenance and inspections.  
* The contents of this manual are subject to change without notice.  
© TOSHIBA SCHNEIDER INVERTER CORPORATION 2005  
All rights reserved.  
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E6581315  
Contents  
1.  
2.  
3.  
General outlines of the communication function......................................................................................................... 3  
Data transmission specifications................................................................................................................................ 4  
Communication protocol............................................................................................................................................. 5  
3.1. About the handling of received frames............................................................................................................... 5  
TOSHIBA Inverter Protocol......................................................................................................................................... 6  
4.1. Data transmission format ................................................................................................................................... 7  
4.1.1.Data transmission format used in ASCII mode......................................................................................... 7  
4.1.2.Data transmission format used in binary mode ...................................................................................... 10  
4.1.3.Transmission format of Block Communication ....................................................................................... 13  
4.2. Commands....................................................................................................................................................... 17  
4.3. Transmission errors ......................................................................................................................................... 20  
4.4. Broadcast communication function.................................................................................................................. 21  
4.5. Examples of the use of communication commands......................................................................................... 23  
4.6. Examples of Communication programs ........................................................................................................... 24  
MODBUS-RTU protocol............................................................................................................................................ 29  
5.1. MODBUS-RTU transmission format .............................................................................................................. 30  
5.1.1.Read command (03)............................................................................................................................... 30  
5.1.2.Write command (06)............................................................................................................................... 31  
5.2. CRC Generation............................................................................................................................................... 32  
5.3. Error codes....................................................................................................................................................... 32  
Inter-drive communication ........................................................................................................................................ 33  
6.1. Proportional control of speed ........................................................................................................................... 37  
6.2. Transmission format for inter-drive communication ......................................................................................... 39  
Communication parameters ..................................................................................................................................... 40  
7.1. Baud rate(, ) , Parity ()................................................................................................ 42  
7.2. Inverter number()................................................................................................................................. 42  
4.  
5.  
6.  
7.  
7.3. Communication time-out time (), Communication time-out action (f804 ............................................................... 43  
)
7.4. Send waiting time (, ) .............................................................................................................. 44  
7.5. Free notes()......................................................................................................................................... 44  
Commands and monitoring from the computer ........................................................................................................ 45  
8.1. Communication commands (commands from the computer) .......................................................................... 45  
8.2. Monitoring from the computer .......................................................................................................................... 49  
8.3. Utilizing panel (LEDs and keys) by communication ......................................................................................... 58  
8.3.1.LED setting by communication............................................................................................................... 58  
8.3.2.Key utilization by communication ........................................................................................................... 61  
Parameter data......................................................................................................................................................... 62  
8.  
9.  
Appendix 1 Table of data codes........................................................................................................................................ 67  
Appendix 2 Response time............................................................................................................................................... 68  
Appendix 3 Compatibility with the communication function of the VF-A7 ......................................................................... 69  
Appendix 4 Troubleshooting ............................................................................................................................................. 70  
Appendix 5 Connecting for RS485 communication........................................................................................................... 71  
2
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E6581315  
1. General outlines of the communication function  
This manual explains the RS485 communication function provided for the TOSVERT VF-AS1 series  
of industrial inverters.  
(1) RS485 communication by the use of a two-wire RS485 communication port (standard function)  
(2) RS485 communication by the use of a four-wire RS485 communication port (standard function)  
(1) 2-wire RS485 communication  
connector  
(2) 4wire RS485 communication  
connector  
By using these communication functions in combination with the computer link function designed to  
establish a link between a higher level computing machine or controller (hereinafter referred to as a  
computer) and each inverter on the network, or with the inter-drive communication function that al-  
lows proportional control of inverters without using a computer, you can set up a network for data  
communication between inverters.  
There are two communication protocols available: Toshiba Inverter Protocol and MODBUS-RTU  
Protocol (this command does not support all commands). To select a protocol, the communication  
protocol selection parameter f807or f829is used. (Refer to Section 3. Communication proto-  
col.)  
<Computer link>  
By preparing the program (explained later), the following information can be exchanged between the  
computer (host) and the inverter.  
(1) Monitoring function (used to monitor the operating status of the inverter: Output frequency,  
current, voltage, etc.)  
(2) Command function (used to issue run, stop and other commands to the inverter)  
(3) Parameter function (used to set parameters and read their settings)  
<Inter-drive communication function>  
Master inverter sends the data, that is selected by the parameter, to all the slave inverters on the  
same network. This function allows a network construction in which a simple synchronous or  
proportional operation is possible among plural inverters (without the host computer).  
As for data communication codes, the TOSVERT VF-AS1 series of inverters support the binary  
(HEX) code, in addition to the JIS (ASCII) code. A communication number is used to access the de-  
sired data item.  
* The smallest unit of information that computers handle is called a “bit (binary digit),” which repre-  
sents the two numbers in the binary system: 1 or 0. A group of 16 bits is referred to as a “word,”  
which is the basic unit of information the VF-AS1 series of inverters use for data communication.  
One word can handle data items of 0 to FFFFH in hexadecimal notation (or 0 to 65535 in decimal  
notation).  
BIT15  
BIT8BIT7  
BIT0  
1 bit  
1 word  
3
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E6581315  
2. Data transmission specifications  
Items  
Specifications  
Transmission scheme  
Half-duplex  
*: Standard  
default setting  
Synchronization scheme  
Communication baud rate 9600/19200*/38400 bps (selectable using a parameter) *1  
Start-stop synchronization  
Communication protocol  
Character transmission  
TOSHIBA Inverter Protocol * / MODBUS-RTU (selectable using a parameter) *1  
<ASCII mode> JIS X 0201 8-bit (ASCII)  
<Binary mode, MODBUS-RTU> Binary codes fixed to 8 bits  
Received by inverter: 1 bit, Sent by inverter: 2 bits *3  
Parity *2: Even */Odd/Non parity (selectable using a parameter) *1  
checksum(Toshiba inverter protocol), CRC(MODBUS-RTU)  
Stop bit length  
Error detecting scheme  
,
Character  
transmission 11-bit characters *1 (Stop bit=1, with parity)  
format  
Order of bit transmission  
Frame length  
Low-order bits transmitted first  
Variable (to a maximum of 17 bytes)  
*1: Changes to setting do not take effect until the inverter is turned back on or reset.  
*2: JIS-X-0201 (ANSI)-compliant 8-bit codes are used for all messages transmitted in ASCII mode  
and vertical (even) parity bits specified by JIS-X-5001 are added to them. These even parity bits  
can be changed to odd parity bits by changing the parameter setting (a change to the parameter  
setting does not take effect until the inverter has been reset.)  
*3: Here are the default character transmission format.  
Characters received: 11 bits (1 start bit + 8 bits + 1 parity bit + 1 stop bit)  
START  
BIT  
PARITY STOP  
BIT BIT  
BIT0  
BIT1  
BIT2  
BIT3  
BIT4  
BIT5  
BIT6  
BIT7  
The inverter receives one stop bit.  
(The computer can be set so as to send 1, 1.5 or 2 stop bits.)  
Characters sent: 12 bits (1 start bit + 8 bits + 1 parity bit + 2 stop bits)  
START  
PARITY STOP  
BIT BIT  
STOP  
BIT  
BIT  
The inverter sends two stop bits.  
(The computer can be set so as to receive 1, 1.5 or 2 stop bits.)  
BIT0  
BIT1  
BIT2 BIT3  
BIT4  
BIT5  
BIT6  
BIT7  
4
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E6581315  
3. Communication protocol  
This communication protocol supports the TOSHIBA Inverter Protocol and part of MODBUS-RTU  
protocol.  
Select the desired protocol from in the following communication protocol selection parameters  
(, ).  
“Parameter Name and , Communication Number. 0807 and 0829”  
Data Range: 0, 1 (Initial value: 0)  
0: TOSHIBA (Includes inter-drive communication)  
1: MOUBUS-RTU  
* A parameter change is reflected when the inverter is reset, such as in power off.  
3.1. About the handling of received frames  
To send and receive data frames, a frame synchronization system for locating the start and end  
points of each frame is defined with time for which no data is sent (time interval equivalent to the  
time required to send 3.5 bytes of data).  
If no data is sent for the time required to send 3.5 bytes of data at the current transmission speed  
(approx. 4 ms or more at 9,600 bps or approx. 2 ms or more at 19,200/38,400 bps) after receipt of a  
frame, the entire frame is assumed to have reached and information in it is analyzed. For this rea-  
son, an interval corresponding to at least 3.5 bytes of data must be placed between frames.  
When sending a significant data set using two or more frames, an interval corresponding to at least  
1.5 bytes of data must be placed between frames. If an interval corresponding to 1.5 bytes or more  
is not placed, the contents of a frame are analyzed separately from those of the other frames, and  
therefore communication are not carried out normally.  
When two or more inverters on the same line are controlled individually one after another, not only  
data from the host computer to an inverter but also a response from an inverter to the host computer  
are transmitted to the other inverters on the line too. Therefore, an interval corresponding to at least  
3.5 bytes should be placed between the time when the host computer receives a response from an  
inverter and the time when it sends a frame to the next inverter. Otherwise the return frame received  
and the frame that is sent immediately after receipt of the return frame will be recognized as one  
frame and communication will not be carried out normally.  
[Correct]  
Frame B  
Frame A  
Note: An inverter cannot receive frame  
3.5 bytes or more  
B before it finishes analyzing the  
contents of frame A.  
[Wrong] If divided into two smaller frames, frame A cannot be received as a  
single frame.  
Frame B  
Frame A (1/2)  
Frame A (2/2)  
1.5 bytes or more  
Note: Correct if the interval corresponds  
to less than 1.5 bytes of data.  
5
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E6581315  
4. TOSHIBA Inverter Protocol  
Select “TOSHIBA” (, =) in the communication protocol selection parameters.  
“TOSHIBA” (, =) is set for initial communication protocol selection of shipment  
setting. (See “3. Communication protocol.”)  
Exchange of data between the computer and the inverter  
In communication between the computer and the VF-AS1 (hereinafter referred to as the inverter),  
the inverter is always placed in wait states and acts as a slave that operates on a request from the  
computer.  
A discrimination between ASCII mode and binary mode is automatically made with the start code.  
Start code  
“(”  
“CR” (carriage return)  
Required  
ASCII mode  
Binary mode  
“2FH(/) ”  
Not required  
(1) If there is no transmission format or the inverter number that matches, an error occurs and no  
response is returned.  
(2) When an inverter number is added behind the “(” communication will take place only in case of  
broadcast communication or if the number matches up with that assigned to the inverters.  
(3) When a time-out period is specified with parameter f803(communication time-out time), a  
time-out occurs if communication do not terminate normally within the specified time. With  
parameter f804(communication time-out action), you can specify what the inverter should do  
if a time-out occurs. For details, refer to Section 7.3.  
(4) On executing the command received, the inverter returns data to the computer. For the response  
time, see Appendix 2, “Response time.”  
Note  
Communication is not possible for about two seconds after the power is supplied to the inverter until  
the initial setting is completed. If the control power is shut down due to an instantaneous voltage  
drop, communication is temporarily interrupted.  
6
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4.1. Data transmission format  
Note: The term “trip status” used in this manual includes retry waiting status and trip retention status.  
4.1.1. Data transmission format used in ASCII mode  
A communication number is used to specify a data item, all data is written in hexadecimal, and JIS-  
X-0201 (ASCII (ANSI))-compliant transmission characters are used.  
Computer Inverter  
 Omissible in one-to-one communication  
For the W and P commands only   Omissible  
(3.5bytes  
Blank) (28H) 2 bytes  
"("  
INV-NO  
CMD Communication No.  
1 byte 4 bytes  
DATA  
"&"  
SUM  
")"  
CR  (3.5bytes  
0 to 4 bytes (26H) 2 bytes (29H) (0DH)  
Blank)  
   Omissible  
      
1. “(“ (1 byte)  
: Start code in ASCII mode  
2. INV-NO (2 bytes) : Inverter number (Omissible in one-to-one communication) ... 00 (30H, 30H) to 99 (39H,  
39h), *(2AH)  
The command is executed only when the inverter number matches up with that specified  
using a parameter.  
(When * is specified in broadcast communication, the inverter number is assumed to match  
if all numbers except * match. When * is specified instead of each digit (two-digit number),  
all inverters connected are assumed to match.)  
If the inverter number does not match or if the inverter number is of one digit, the data will  
be judged invalid and no data will be returned.  
3. CMD (1 byte)  
4. Communication No.(4 bytes)  
: Communication number (See 11, “Parameter data.”)  
5. Data (0 to 4 bytes): Write data (valid for the W and P commands only)  
: Command (For details, see the table below.)  
6. “&” (1 byte)  
: Checksum discrimination code (omissible. When omitting this code, you also need to omit  
the checksum.)  
7. Sum (2 bytes)  
: Checksum (omissible)  
Add the ASCII-coded value of the last two digits (4 bits/digit) of the sum of a series of bits  
(ASCII codes) from the start code to the checksum discrimination code.  
Ex.: (R0000&??) CR  
28H+52H+30H+30H+30H+30H+26H=160H  
The last two digits represent the checksum. = 60  
When omitting the checksum, you also need to omit the checksum discrimination  
code.  
8. “)” (1 byte)  
9. CR (1 byte)  
: Stop code (omissible)  
: Carriage return code  
Details of commands and data  
CMD (1 byte)  
Write data (0 to 4 bytes) Hexadecimal number  
No data  
Write data (0 to FFFF)  
R (52H): RAM read command  
W (57H): RAM/EEPROM write command  
P (50H) RAM write command  
Write data (0 to FFFF)  
7
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Inverter computer  
At time of broadcast communication, returning of data is not executed, except for the inverters to be  
returned, when the inverter number is not matched, and the inverter number has only one character.  
This is because there will be a risk of that the returned data may be deformed.  
Data returned when data is processed normally (ASCII mode)  
 Omissible in one-to-one communication  
Omissible  
SUM ")"  
(3.5bytes  
Blank) (28H) 2 bytes  
"("  
INV-NO  
CMD Communication No.  
1 byte 4 bytes  
DATA  
"&"  
CR  (3.5bytes  
0 to 4 bytes (26H) 2 bytes (29H) (0DH)  
Blank)  
   Omissible  
      
1. “(“ (1 byte)  
: Start code in ASCII mode  
2. INV-NO (2 bytes) : Inverter number (omitted if it is not found in the data received) ... 00 (30H, 30H) to 99 (39H,  
39H)  
If the inverter number matches up with that specified using a parameter, data will be return-  
ed to the computer. In broadcast communication, only the destination inverter (with a num-  
ber matching up with the smallest effective number) returns data to the computer.  
In broadcast communication, no data is returned from any inverters except the inverter  
bearing a number that matches up with the smallest effective number.  
Ex.: (*2R0000) CR -> (02R00000000) CR)  
Data is returned from the inverter with the number 2 only, but no data is returned from  
inverters with the number 12, 22 ....  
3. CMD (1 byte)  
: Command ... The command is also used for a check when an inverter is tripped.  
Under normal conditions... The uppercase letter R, W or P is returned, depending on the  
command received: R, W or P command.  
When an inverter is tripped... The lowercase letter r, w or p is returned, depending on the  
command received: R, W or P command.  
(The command received is returned with 20H added to it.)  
4. Communication No.(4 bytes) :  
The communication number received is returned.  
5. Data (0 to 4 bytes): Data ... The data read in is returned for the R command, while the data received is returned  
for the W and P commands. If the data received is composed of less than 4 digits, it will be  
converted into 4-digit data and returned.  
Ex.: (W123412) CR (W12340012) CR)  
6. “&” (1 byte)  
: Checksum discrimination code (omitted if it is not found in the data received)  
7. Sum (2 bytes)  
: Checksum ... Omitted if no checksum discrimination code is found in the data received.  
ASCII-coded value of the last two digits (4 bits/digit) of the sum of a series of bits (ASCII  
codes) from the start code to the checksum discrimination code.  
8. “)” (1 byte)  
9. CR (1 byte)  
: Stop code (omitted if it is not found in the data received)  
: Carriage return code  
8
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Data returned when data is not processed normally (ASCII mode)  
In case an error occurs, communication error command (4EH(N) or 6EH(n)) and the error type num-  
ber is returned to the computer in addition to the checksum. At time of broadcast communication of  
the binary mode, returning of data is not executed except for the inverter to be returned (inverter  
number 00H) and when the inverter number is not matched. This is because there will be a risk that  
the returned data may be deformed.  
Omissible                           Omissible  
(3.5bytes “(“  
INV-NO  
“N” or “n”  
DATA  
"&"  
SUM  
")"  
CR (3.5bytes  
Blank) (28H) 2 bytes  
(4EH)  (6EH)  
4 bytes  
(26H)  
2 bytes  
(29H) (0DH) Blank)  
   Omissible  
 
“(“ (1 byte)  
: Start code in ASCII mode  
“N” or “n” (1 byte)  
:Communication error command ... This is also used for the checking of inverter trip.  
“N” for the normal communication and “n” during the inverter trip.  
INV-NO (2 bytes)  
Data (4 bytes)  
: Inverter number (omitted if it is not found in the data received) ... 00 (30H, 30H) to 99 (39H,  
39H)  
If the inverter number matches up with that specified using a parameter, data will be return-  
ed to the computer. In broadcast communication, only the destination inverter (with a num-  
ber matching up with the smallest effective number) returns data to the computer.  
: Error code (0000~0004)  
0000 ... Impossible to execute (Although communication is established normally, the  
command cannot be executed because it is to write data into a parameter whose  
setting cannot be changed during operation (e.g., maximum frequency) or the  
EEPROM is faulty.)  
0001 ... Data error (The data is outside the specified range or it is composed of too many  
digits.)  
0002 ... Communication number error (There is no communication number that matches.)  
0003 ... Command error (There is no command that matches.)  
0004 ... Checksum error (The checksum result differs.)  
“)” (1 byte)  
: Stop code ... This code is omitted if it is not found in the data received.  
Examples:  
(N0000&5C)CR... Impossible to execute (e.g., a change of maximum frequency data during opera-  
tion)  
(N0001&5D)CR... Data error (Data is outside the specified range.)  
(N0002&5E)CR... No communication number (There is no communication number that matches.)  
(N0003&5F)CR... There is no command that matches. (Commands other than the R, W and P  
commands)  
(Ex.: L, S, G, a, b, m, r, t, w ...)  
(N0004&60)CR... Checksum error (The checksum result differs.)  
No data returned ... Format error or invalid inverter number  
9
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4.1.2. Data transmission format used in binary mode  
A communication number is used to specify a data item, data is written in hexadecimal form, and  
data in transmission characters are represented by binary codes (HEX codes).  
Computer Inverter (binary mode)  
Omissible in one-to-one communication     No data for the 52H (R) command  
(3.5bytes  
Blank) (2FH)  
“/”  
INV-NO  
1 byte  
CMD  
1 byte  
Communication No.  
2 bytes  
DATA  
2 bytes  
SUM  
1 byte  
(3.5bytes  
Blank)  
            
 
Checksum area  
        Not omissible  
1. 2FH (“/”) (1 byte) : Start code in binary mode  
2. INV-NO (2 bytes) : Inverter number (Omissible in one-to-one communication) ... 00H to 3FH ,FFH  
In case the inverter number is other than FFH (broadcast communication), command is ex-  
ecuted only when the inverter number coincides with the one designated with the panel. If  
the inverter number is not matched, it will be judged invalid and the data is not returned.  
3. CMD (1 byte)  
: Command (For details, see the table below.)  
52H (R) command: The size of the data following CMD is fixed to 3 bytes. (Communication  
number: 2 bytes, checksum: 1 byte)  
57H (W), 50H (P) and 47H (G) commands: The size of the data following CMD is fixed to 5  
bytes.  
(Communication number: 2 bytes, data: 2 byte, checksum: 1 byte)  
Any command other than the above is rejected and no error code is returned.  
4. Communication No.(2 bytes)  
: Communication number (See 11, “Parameter data.”)  
5. Data (2 bytes)  
: 0000H to FFFFH  
57H (W) and 50H (P) commands: Write data (An area check is performed.)  
47H (G) command: Dummy data (e.g., 0000) is needed.  
52H (R) command: Any data is judged invalid. (No data should be added.)  
6. Sum (2 bytes)  
: Checksum (not omissible) 00H to FFH  
Value of the last two digits (1 byte) of the sum of a series of bits (codes) from the start code  
of the data returned to the data (or to the communication number for the 52H (R) com-  
mand)  
Ex.: 2F 52 00 ?? ... 2FH+52H+00H+00H=81H  
The last two digits (??) represent the checksum= 81  
Details of commands and data  
CMD (1 byte)  
Write data (2 bytes) Hexadecimal number  
No data  
52H (R): RAM read command  
57H (W): RAM/EEPROM write command  
50H (P): RAM write command  
47H (G): RAM read command (for two-wire networks)  
Write data (0000H to FFFFH)  
Write data (0000H to FFFFH)  
Dummy data (0000H to FFFFH)  
10  
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E6581315  
Inverter computer (binary mode)  
At time of broadcast communication of the binary mode, returning of data is not executed except for  
the inverter to be returned (inverter number 00H) and when the inverter number is not matched. This  
is because there will be a risk that the returned data may be deformed.  
Data returned when data is processed normally (Binary mode)  
Omissible  
(3.5bytes  
Blank) (2FH)  
“/”  
INV-NO  
1 byte  
CMD  
1 byte  
Communication No.  
2 bytes  
DATA  
2 bytes  
SUM  
1 byte  
(3.5bytes  
Blank)  
            
 
Checksum area  
        Not omissible  
1. 2FH (“/“) (1 byte) : Start code in binary mode  
2. INV-NO (2 bytes) : Inverter number... 00H to 3FH (The inverter number is omitted if it is not found in the data  
received.)  
If the inverter number matches up with that specified from the operation panel, data will be  
returned from the inverter. If the inverter number does not match, the data will be invalid  
and no data will be returned.  
3. CMD (1 byte)  
: Command...The command is also used for a check when the inverter is tripped.  
Under normal conditions...52H (R), 47H (G), 57H (W) or 50H (P) is returned, depending on  
the command received.  
When the inverter is tripped...The lowercase letter 72H (r), 67H (g), 77H (w) or 70H (p) is  
returned with 20H added to it, depending on the command received.  
4. Communication No. (4 bytes)  
: The communication number received is returned.  
5. Data (2 bytes)  
: Data ... 0000H to FFFFH  
The data read is returned for the 52H (R) and 47H (G) commands, while the data written is  
returned for the 57H (W) and 50H (P) commands.  
6. Sum (1 bytes)  
: Checksum (not omissible) 00H to FFH  
Value of the last two digits (1 byte) of the sum of a series of bits (codes) from the start code  
to the data.  
11  
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2) Error Processing (Binary mode)  
In case an error occurs, communication error command (4EH(N) or 6EH(n)) and the error type num-  
ber is returned to the computer in addition to the checksum. At time of broadcast communication of  
the binary mode, returning of data is not executed except for the inverter to be returned (inverter  
number 00H) and when the inverter number is not matched. This is because there will be a risk that  
the returned data may be deformed.  
Omissible  
         
(3.5bytes “/”  
Blank) (2FH) 1 byte  
 
INV-NO  
Norn  
(4EH)(6EH)  
DATA  
2 bytes  
SUM  
1 byte  
(3.5bytes  
Blank)  
Checksum area         Not omissible  
     
Norn (1 byte)  
Data (2 bytes)  
: Communication error command ... This command is also used for a check when the in-  
verter is tripped.  
4EH (N)” is returned under normal conditions, while “6EH (n)” is returned when the in-  
verter is tripped.  
: Error code (0000~0004)  
0000 ... Impossible to execute (Although communication is established normally, the com-  
mand cannot be executed because it is to write data into a parameter whose set-  
ting cannot be changed during operation (e.g., maximum frequency) or the  
EEPROM is faulty.)  
0001 ... Data error (The data is outside the specified range or it is composed of too many  
digits.)  
0002 ... Communication number error (There is no communication number that matches.)  
0004 ... Checksum error (The checksum result differs.)  
No code returned ...Command error, format error (failure to receive the specified number of  
bytes within 0.5 seconds, or an parity, overrun or framing error) or the  
inverter number does not match or an inverter in broadcast communi-  
cation in the binary mode except for the inverter for data returning (the  
inverter numbered 00H).  
Examples:  
2FH, 4EH, 00H, 00H, 7DH ... Impossible to execute (e.g., a change of maximum frequency data  
during operation)  
2FH, 4EH, 00H, 01H, 7EH ... Data setting error (The data specified falls outside the specified  
range.)  
2FH, 4EH, 00H, 02H, 7FH ... No communication number (There is no communication number that  
matches.)  
2FH, 4EH, 00H, 04H, 81H ... Checksum error (The checksum result differs.)  
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4.1.3. Transmission format of Block Communication  
What is block communication?  
Data can be written in and read from several data groups set in one communication by setting the  
type of data desired for communication in the block communication parameters (, ,  
 to ) in advance. Block communication can save the communication time.  
Data is transmitted hexadecimal using the binary (HEX) code transmission characters. “Computer  
inverter” is for writing only, while “Inverter computer” for reply is for reading only.  
Computer Inverter (Block Communication)  
Number of writing data groups x 2 bytes  
Omissible  
INV-NO  
Num-  
ber of  
write  
Num-  
ber of  
read  
(3.5bytes  
Blank)  
Start  
Code  
”  
CMD  
“X”  
Write  
data1  
High  
Write  
data1  
Low  
Write  
data2  
High  
Write  
data2  
Low  
SUM (3.5bytes  
Blank)  
data  
data  
groups  
groups  
Checksum Area  
1. 2FH(“/”) (1 byte) : Start code of binary mode  
2. INV-NO (1 byte) : Inverter number. (Can be omitted in 1:1 communication): 00H to 3FH, FFH  
Executed only when the inverter number matches the inverter number. Set on the panel, ex-  
cept in FFH (broadcast communication).  
Communication data will be invalidated and data will not be returned either if the inverter  
number. Does not match.  
3. CMD (1 byte)  
4. Number of write data groups (1 byte)  
: Specify the number of data groups to be written (00H to 02H).  
: ‘X’ (Block communication command)  
If specified outside of the range, data will be treated as a format error and data will not be re-  
turned.  
5. Number of read data groups (1 byte)  
: Specify the number of data groups to be read (00H to 05H).  
If specified outside of the range, data will be returned as “Number of read data groups = 0”  
when returned by the inverter.  
6. Write data1 (2 bytes)  
: Needed when the number of write data groups is larger than 1.  
Data to be written to the specified parameter selected by   
Dummy data is needed if the number of write data groups is larger than 1 even though(none)  
is selected for   
7. Write data2 (2 bytes)  
: Needed when the number of write data groups is 2.  
Data to be written to the specified parameter selected by   
Dummy data is needed if the number of write data groups is 2 even though(none) is selected  
for   
8. SUM (1 byte)  
: Checksum (Cannot be omitted) 00H to FFH  
Lower two digits (1 byte) of total sum from start code (SUM value not included)  
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Block Write 1, 2  
Select data, which is desired to be written in block communication, in block write Data 1 and 2 Pa-  
rameters (, ). This parameter becomes effective when the system is reset, such as  
when power is turned off. When the setting is completed, turn off and then on the power.  
No. Block Write Data  
For data details, see:  
0
1
2
3
4
5
Deselect  
 -  
Command information 1 (FA00)  
Command information 2 (FA20)  
Frequency Command (FA01)  
Terminal board output data (FA50)  
Communication analog output (FA51)  
“8.1 Command by communication”  
* When “Deselect” is specified in the parameters, no data will be written even though write data is  
specified.  
Block Read 1 to 5  
Select read data, which is desired to be read in block communication, in block read data 1 and 5 Pa-  
rameters (to). This parameter becomes effective when the system is reset,  
such as when power is turned off. When the setting is completed, turn off and then on the power.  
No. Block Read Data  
For data details, see:  
0
1
Deselect  
 -  
Status information (FD01)  
Output frequency (FD00)  
Output current (FD03)  
2
3
4
Output voltage (FD05)  
5
Alarm Information (FC91)  
PID feedback value (FD22)  
Input terminal board monitor (FD06)  
Output terminal board monitor (FD07)  
V/II terminal boad monitor (FE36)  
RR/S4 terminal board monitor (FE35)  
RX terminal board monitor (FE37)  
Input voltage (DC detection) (FD04)  
Speed feedback frequency (FD16)  
Torque (FD18)  
6
7
“8.2 Monitoring from communication”  
8
9
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
My monitor 1(FE60)  
 -  
My monitor 2(FE61)  
 -  
My monitor 3(FE62)  
 -  
My monitor 4(FE63)  
 -  
Free notes (F880)  
“7.5 Free notes ()”  
* V/II terminal board monitor (FE36), RR/S4 terminal board monitor (FE35) and RX terminal board  
monitor (FE37) will become hold data during a trip. Otherwise, real-time data appears.  
* “0000” will be returned as dummy data, if “0 (Deselect)” is selected for the parameter and “read” is  
specified.  
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Inverter Computer  
At time of broadcast communication of the binary mode, returning of data is not executed except for  
the inverter to be returned (inverter number 00H) and when the inverter number is not matched. This  
is because there will be a risk that the returned data may be deformed.  
1) Normal processing  
Omissible  
Number of read data groups x 2 bytes  
(3.5  
bytes Code  
Blank) “/”  
Start  
INV CMD  
No. “Y”  
Write Read Read Read Read Read Read Read Read Read Read SUM  
Status data1 data1 data2 data2 data3 data3 data4 data4 data5 data5  
(3.5  
bytes  
Blank)  
Number  
of Read  
Data  
high  
low  
high  
low  
high  
low  
high  
low  
high  
low  
Groups  
Checksum area  
1. 2FH “/” (1 byte)  
2. INV-NO (1Byte)  
Start code in binary mode  
Inverter number・・・00H to 3FH  
If the inverter number matches up with that specified from the operation panel, data will  
be returned from the inverter. If the inverter number does not match, the data will be  
judged invalid and no data will be returned.  
Communication data will be invalidated and data will not be returned either if the in-  
verter number does not match. (Inverter number is considered matched if it is omitted  
during reception)  
3. CMD(1Byte)  
:‘Y’ (Block communication command [monitoring])  
Lowercase letter ‘y’ during an inverter trip, including standing by for retrying and during  
a trip.  
4. Number of read data groups (1 byte)  
: Return the number of data groups to be read (00H to 05H).  
5. Write status (1 byte) : Return 00H to 03H.  
* Failing to write in the specified parameter in the number of write data groups, set “1”  
in the corresponding bit for the parameter failed to write. (See below.)  
Bit Position  
Data Type  
7
6
5
4
3
2
1
0
   
6. Read data1 - 5 (2 bytes)  
: Return according to the number of read data groups. “0000H” is returned as dummy  
data if “0” is selected as a parameter.  
Read data1: Data selected by . Read data2: Data selected by .  
Read data3: Data selected by . Read data4: Data selected by .  
Read data5: Data selected by .  
7.SUM(1Byte)  
: Checksum (Cannot be omitted) 00H to FFH  
Lower two digits (1 byte) of total sum from start code of return data to read data.  
Example  
(When set as follows:  = (Command information 1),  = (frequency command),  
 = (status information), = (output frequency),  = (output current),  = (output  
voltage) and  = (alarm information)  
Computer Inverter2F 58 02 05 C4 00 17 70 D9  
Inverter Computer2F 59 05 03 00 00 00 00 00 00 00 00 00 00 90 (When parameter is not set)  
Inverter Computer2F 59 05 00 40 00 00 00 00 00 00 00 00 00 CD CD (When parameter is set)  
Inverter Computer2F 59 05 00 64 00 17 70 1A 8A 24 FD 00 00 3D (During operation at 60Hz)  
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2) Error Processing (Binary mode)  
In case an error occurs, communication error command (4EH(N) or 6EH(n)) and the error type num-  
ber is returned to the computer in addition to the checksum.  
Omissible  
         
(3.5bytes “/”  
Blank) (2FH) 1 byte  
 
INV-NO  
Norn  
(4EH)(6EH)  
DATA  
2 bytes  
SUM  
1 byte  
(3.5bytes  
Blank)  
Checksum area         Not omissible  
     
“N” or “n” (1 byte) : Communication error command. Also for check during an inverter trip (includes standing  
by for retrying and trip holding). “4EH (N)” when normal, “6EH (n)” during an inverter trip.  
DATA (2 bytes)  
: Error code (0004)  
0004  
: Checksum error (The checksum does not match)  
No return : Command error, format error (specified number of bytes is not received in 1sec,  
or parity error, overrun error or framing error), inverter number mismatch, and  
inverter number other than 00H in broadcast communication.  
Examples  
Computer Inverter : 2F 58 02 05 C4 00 17 70 D8  
Inverter Computer : 2F 4E 00 04 81 ... Checksum error  
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4.2. Commands  
Here are the communication commands available.  
Command  
R command Reads the data with the specified communication number.  
Function  
W command Writes the data with the specified communication number. (RAM and EEPROM).  
P command Writes the data with the specified communication number. (RAM).  
Reads the data with the specified communication number. (For binary mode only.  
Dummy data is required for this command.)  
G command  
X command Block communication (Computer -> Inverter)  
Y command Block communication (Inverter -> Computer)  
W (57H) (RAM*1 /EEPROM*2 write)  
This command is used to write new data into the parameter specified using it communication num-  
ber. It writes data into the RAM and EEPROM. For parameters whose settings cannot be stored in  
the EEPROM (e.g., parameter with the communication number FA00), the W (57H) command writes  
data into the RAM only. It cannot be used to write data into read-only parameters (e.g., parameter  
with the communication number FD?? or FE??).  
Each time an attempt to write data is made, the inverter checks if the data falls within the specified  
range. If this check reveals that the data falls outside the specified range, the inverter will reject it  
and return an error code.  
- Ex.: Setting the deceleration time (communication number: 0010) to 10 sec.  
CR: Carriage return  
<ASCII mode>  
Computer Inverter  
(W00100064)CR  
Inverter Computer  
(W00100064)CR  
…(10÷0.1=100=0064H)  
<Binary mode>  
Computer Inverter  
2F 57 00 10 00 64 FA  
Inverter Computer  
2F 57 00 10 00 64 FA  
…(10÷0.1=100=0064H)  
Notice  
Do not write the same parameter to the EEPROM more than 10,000 times. The life time of EEPROM is  
approximately 10,000 times.(Some parameters are not limited, please refer to the “9.Parameter data “)  
The lifetime of EEPROM is approximately 10,000 times. When using the TOSHIBA inverter protocol and  
the data does not need to be records, use P command (the data is written only to RAM).  
Explanation of terms  
*1: The RAM is used to temporarily store inverter operation data. Data stored in the RAM is cleared  
when the inverter is turned off, and data stored in the EEPROM is copied to the RAM when the  
inverter is turned back on.  
*2: The EEPROM is used to store inverter operation parameter settings, and so on. Data stored in  
the EEPROM is retained even after the power is turned off, and it is copied to the RAM when the  
inverter is turned on or reset.  
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P (50H) (RAM*1 write)  
This command is used to rewrite data into the parameter specified using a communication number.  
It writes data into the RAM only. It cannot be used to write data into any read-only parameters. Each  
time an attempt to write data is made the inverter checks whether the data falls within the specified  
range. If this check reveals that the data falls outside the range, the inverter will reject it and return  
an error code.  
- Ex.: Entering the emergency stop command (communication number: FA00) from the computer  
<ASCII mode>  
Computer Inverter  
Inverter Computer  
(PFA009000)CR  
(PFA009000)CR  
Command priority, emergency stop  
command  
<Binary mode>  
Computer Inverter  
2F 50 FA 00 90 00 09  
Inverter Computer  
2F 50 FA 00 90 00 09  
R (52H) (Data read)  
This command is used to read the setting of the parameter specified using a communication num-  
ber.  
- Ex.: Monitoring the electric current (communication number: FE03)  
<ASCII mode>  
Computer Inverter  
(RFE03)CR  
Inverter Computer  
(RFE03077B)CR  
…Current: 1915 / 100 = 19.15%  
<Binary mode>  
Computer Inverter  
2F 52 FE 03 82  
Inverter Computer  
2F 52 FE 03 07 7B 04  
G (47H) (Data read)  
This command is used to read the parameter data specified using a communication number. Alt-  
hough this command is used for the previous model to control the operation of two or more inverters  
in binary mode through a two-wire RS485 network, the “R” command can also be used without  
problems for the VF-AS1 series.  
To use the “G” command, however, dummy data (2 bytes) is needed.  
This command is available only in binary mode.  
- Ex.: Monitoring the electric current (communication number: FE03)  
Computer Inverter  
Inverter Computer  
2F 47 FE 03 00 00 77  
2F 47 FE 03 07 7B F9  
* In this example, the data 00H sent from the computer to the inverter is dummy data.  
S (53 H)/ s (73 H) Inter-drive communication command(RAM*1 Write)  
This command is for using frequency command values in % (1 = 0.01%), instead of in Hz, and is for  
synchronous-proportional operation in inter-drive communication. This command can also be  
used in ordinary computer link communication.  
When writing in the frequency command (FA01, FA05) is enabled and a parameter other than it is  
specified, a communication number error will result. Data is written in the RAM only and at this  
time the data check such as an upper limit and lower limit checking is not carried out.  
Data is not returned from the inverters while this command is used. This command can be used  
only in the binary mode.  
For the details of the format, see “6.2 Transmission format for inter-drive communication.”  
Use (%) as the unit for frequency command values specified by the command S, instead of (Hz),  
and the receiving side converts units for frequency values to “Hz” in accordance with the point con-  
version parameter. The conversion formula is shown below.  
Frequency command value (Hz) =  
Point 2 frequency (F813) Point 1 frequency (F812)  
x (Frequency command value (%)  
Point 2 (F814) Point 1 (F811)  
Point 1 (F811) + Point 1 frequency (F812)  
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When Command “s” (lowercase letter) is received, the slave side judges that the master side is  
tripped and operates in accordance with the inter-drive communication parameter (,  
).  
For detail, see "7. Communication parameters ".  
- Examples: 50% frequency command (2-wire RS485 communication)  
(If maximum frequency = Frequency for operation at 80Hz = 40Hz: 50% = 5000d = 1388H)  
<Binary mode>  
Master inverter Slave inverter  
Slave inverter Master inverter  
2F 53 FA 01 13 88 18  
No return  
X(58H)/Y (59H) (Block Communication Command)  
Data selected in the block communication write parameters (,) is written in the  
RAM. When returning data, data selected in block communication read parameters ( to  
) is read and is returned.  
For detail, see "4.1.3. Transmission format of Block Communication ".  
- Examples: 60Hz operation command from communication and monitoring (Monitoring when al-  
ready operating at 60Hz)  
(Parameter Setting:  = , = ,  = ,  = ,  = ,  =  
, = )  
<Binary mode>  
Computer Inverter  
Inverter Computer  
2F 58 02 05 C4 00 17 70 D9  
2F 59 05 00 64 00 17 70 1A 8A 24 FD 00 00 3D  
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4.3. Transmission errors  
Table of error codes  
Error name  
Description  
Error code  
Impossible to exe- The command is impossible to execute, though communication was  
0000  
cute  
established normally.  
1 Writing data into a parameter whose setting cannot be changed  
during operation (e.g., maximum frequency) *1  
2 Writing data into a parameter while “” is in progress  
Invalid data is specified.  
Data error  
0001  
0002  
Communication  
number error  
Command error  
There is no communication number that matches.  
The command specified does not exist.  
0003 (ASCII mode)  
No code returned (Binary  
mode)  
Checksum error  
Format error  
The Checksum does not match.  
0004  
The data transmission format does not match.  
1 One-digit inverter number (ASCII mode)  
2 The CR code is found in the designated position. (ASCII mode)  
Ex.:Communication number of 4 digit or less. In the case of (R11)  
CR, 11) CR is recognized as a communication number and  
the CR code is not recognized, with the result that a format  
error occurs.  
No code returned  
3 A code other then the stop code (“)”) is entered in the stop code  
position.  
Receiving error  
A parity, overrun or framing error has occurred. *2  
No code returned  
*1: For parameters whose settings cannot changed during operation, see ”Table of parameters.”  
*2: Parity error : The parity does not match.  
Overrun error : A new data item is entered while the data is being read.  
Framing error : The stop bit is placed in the wrong position.  
* For the errors with “no code returned” in the above table, no error code is returned to avoid a data  
crash.  
If no response is received, the computer side recognizes that a communication error has occurred.  
Retry after a lapse of some time.  
* If the inverter number does not match, no processing will be carried out and no data will be re-  
turned, though it is not regarded as an error.  
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4.4. Broadcast communication function  
Broadcast communication function can transmit the command (write the data) to multiple inverters  
by one communication. Only the write (W, P) command is valid and the read (R, G) command is in-  
valid. The inverters subject to the broadcast communication are the same to the independent com-  
munication; 0 to 99 (00H - 63H) in the ASCII mode, and 0 to 63 (00H - 3FH) in the binary mode. To  
avoid data deforming, the inverters to return data will be limited.  
“Overall” broadcast communication (ASCII mode / Binary mode)  
- ASCII Mode  
If you enter two asterisks (**) in the inverter number position of the data transmission format, the  
computer will send the data simultaneously to all inverters (with an inverter number between 0 and  
99 (00 to 63H)) on the network.  
- Binary Mode  
To put "FF" to the specified place of the inverter number in the communication format validates the  
broadcast communication and the command is transmitted to all the applicable inverters in the net-  
work (inverter numbers from 0 to 63 (00 to 3FH)).  
<Inverter that returns data to the computer>  
Data is returned from the inverter bearing the inverter number 00 only.  
If you do not want inverters to return data, do not assign the number 00 to any inverter on the net-  
work.  
“Group” broadcast communication (ASCII mode only)  
If you put “*?” In the inverter number position of the data transmission format, data will be sent  
simultaneously to all inverters bearing a number whose digit in the one’s place in decimal notation  
is”?”  
If you put ”?*” In the inverter number position of the data transmission format, the data will be sent  
simultaneously to all inverters bearing a number whose digit in the ten’s place in decimal notation  
is”?”.  
(“?”: Any number between 0 and 9.)  
<Inverter that returns data to the computer>  
Data is returned only from the inverter bearing the smallest number in the same group of inverters  
(i.e., inverter whose number in the position of ”*” is 0).  
If you do not want inverters to return data to the computer, do not assign a number having a 0 in the  
position of “*” to any inverter on the network.)  
Examples of broadcast communication  
Ex: Set the frequency setting for communication to 60Hz.  
1 Host computer Multiple inverters: broadcast communication (ASCII Mode)  
Example of transmission of data from host computer to inverter: (**PFA011770)CR  
Example of data returned from inverter to host computer: (00PFA011770)CR  
Data is returned from the inverter numbered 00 only, while commands are issued to all inverters  
connected to the network.  
2 Host computer A specific group of inverters: group communication (ASCII Mode)  
Example of transmission of data from host computer to inverters: (*9PFA011770)CR  
Example of data returned from inverter to host computer: (09PFA011770)CR  
Data is returned only the inverter numbered 09 only, while commands are issued to a maximum  
of 10 inverters bearing the number 09, 19, 29, 39, ... or 99.  
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Host  
computer  
Block 2  
Block 1  
Inverter No.20 Inverter No.21  
Inverter No.29  
VF-AS1  
Inverter No. 10 Inverter No.11  
Inverter No.19  
VF-AS1  
VF-AS1  
VF-AS1  
VF-AS1  
VF-AS1  
*1  
*1: Error signal I/F  
In broadcast communication, only the representative inverter in each block returns data to the host  
computer. However, you can make the representative inverter in each block report the occurrence of  
a problem in the block. To do so, follow these steps.  
Set the timer function so that, if a time-out occurs, the inverter will trip (Ex.: =(sec)), set  
the output terminal selection parameter (FL) so that trip information will be output through the output  
terminal (=), and set the input terminal selection parameter (F) of the representative in-  
verter in each block to “external input trip (emergency stop)” (=). Then, connect the input  
terminal (F, CC) of the representative inverter to the FL terminal (FLA, FLC) of each of the other in-  
verters in the same block (FLA-F, FLC-CC). In this setting, if an inverter trips, the representative in-  
verter will come to an emergency stop, and as a result it will report the occurrence of a problem in its  
block to the computer. (If the representative inverter returns a lowercase letter in response to a  
command from the computer, the computer will judge that a problem has arisen in an inverter.) To  
examine details on the problem that has arisen, the host computer accesses each individual inverter,  
specifying its communication number. To make the computer issue a command to all inverters in  
block 1 or block 2 shown in the figure above, specify “1*” or “2*”, respectively. In this system, inverter  
No. 10 will return data to the computer if a problem arises in block 1, or inverter No. 20 if a problem  
arises in block 2. For overall broadcast communication, specify “**”, in which case the inverter with  
the communication number “00” will return data to the computer.  
In this example, if you want the computer to maintain communication without bringing an represen-  
tative inverter to an emergency stop, set its input terminal selection parameter to “disabled  
(=) but not to “external input trip (emergency stop).” This setting causes the host computer  
to check the setting of the input terminal information parameter (Communication No.=DF06, bit 0) of  
the representative inverter, and as a result enables the computer to detect the occurrence of a  
problem.  
CAUTION:  
Data from inverters will be deformed if inverters of the same number are connected on the network.  
Never assign same single numbers to inverters on the network.  
22  
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4.5. Examples of the use of communication commands  
Here are some examples of the use of communication commands provided for the VF-AS1 series of  
inverters.  
Inverter numbers and checksum used in ASCII mode are omitted from these examples.  
Examples of communication  
- To run the motor in forward direction with the frequency set to 60 Hz from the computer  
<ASCII mode>  
Computer Inverter  
Inverter Computer  
(PFA011770)CR  
(PFA011770)CR  
…Set the operation frequency to 60 Hz.  
(60 / 0.01 Hz = 6000 = 1770H)  
(PFA00C400)CR  
(PFA00C400)CR  
…Set to “forward run” with commands and frequency  
instruction from the computer enabled.  
<Binary mode>  
Computer Inverter  
2F 50 FA 01 17 70 01  
Inverter Computer  
2F 50 FA 01 17 70 01  
2F 50 FA 00 C4 00 3D 2F 50 FA 00 C4 00 3D  
- To monitor the output frequency (during 60 Hz operation)  
<ASCII mode>  
Computer Inverter  
Inverter Computer  
(RFD00)CR  
(RFD001770)CR  
…Set the operation frequency to 60 Hz.  
(60÷0.01Hz=6000=1770H)  
<Binary mode>  
Computer Inverter  
2F 52 FD 00 7E  
Inverter Computer  
2F 52 FD 00 17 70 05  
- To monitor the status of the inverter  
<ASCII mode>  
Computer Inverter  
Inverter Computer  
(RFD01)CR  
(rFD010003)CR  
…For details on statuses, see 8.2 “Monitoring from  
the computer.” (Stop status, FL output status, trip  
status (r command))  
<Binary mode>  
Computer Inverter  
2F 52 FD 01 7F  
Inverter Computer  
2F 72 FD 01 00 03 A2  
- To check the trip code (when the inverter is tripped because of )  
…For details on trip codes, see “Trip code monitor” in 8.2, “Monitoring  
from the computer.” (18H = 24d “” trip status)  
<ASCII mode>  
Computer Inverter  
(RFC90)CR  
Inverter Computer  
(rFC900018)CR  
<Binary mode>  
Computer Inverter  
2F 52 FC 90 0D  
Inverter Computer  
2F 72 FC 90 00 18 45  
23  
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4.6. Examples of Communication programs  
According to the hardware configuration of the computer used, select a serial output port. To use an  
RS232C port on the computer, you will have to prepare an RS232C-RS485 conversion unit sepa-  
rately.  
An USB-RS485 conversion unit (USB0001Z) is available as our standard offering.  
Ex. 1: BASIC program for monitoring the output frequency continuously (RS232C, ASCII mode)  
(Toshiba version of Advanced BASIC-86 Ver. 3.01.05J)  
Monitoring the output frequency continuously  
1) Examples of programs  
10 OPEN "COM1:9600,E,8,1" AS #1  
20 A$=”FE00”  
--- 9600 baud, even parity, 8-bit length, 1 stop bit  
--- Specifies the communication number for  
monitoring the output frequency.  
--- Transmits data to the inverter.  
Note: The carriage return code is added  
automatically.  
30 PRINT #1,"("+”R”+A$+")"  
40 INPUT#1,B$  
50 AAA$=“&H”+MID$(B$,7,4)  
--- Receives data returned from the inverter.  
--- Extracts only data items from the data re-  
turned.  
60 F$=LEFT$(STR$(VAL(AAA$)/100),6)  
70 PRINT " Output frequency =";F$+“Hz”  
80 GOTO 20  
--- Converts data into decimal form.  
--- Displays the output frequency.  
--- Repeats.  
2) Examples of program execution results (stop command issued during 80 Hz operation)  
Output frequency = 80 Hz ...  
Output frequency = 79.95Hz  
:
:
Output frequency = 0Hz  
24  
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Ex. 2: BASIC program for executing an input command with checksum (RS232C, ASCII mode)  
(Toshiba version of Advanced BASIC-86 Ver. 3.01.05J)  
Checking if the maximum frequency setting has been changed correctly  
1) Examples of programs  
10 OPEN "COM1:9600,E,8,1" AS #1  
--- 9600 baud, even parity, 8-bit length, 1 stop bit  
--- Reads in data to be sent to the inverter.  
--- Adds “(“ and “&” to the read data in.  
20 INPUT"Send Data=";A$  
30 S$="("+A$+"&"  
40 S=0  
50 L=LEN(S$)  
60 FOR I=1 TO L  
Calculates the number of bits (checksum).  
70 S=S+ASC(MID$(S$,I,1))  
80 NEXT I  
90 CHS$=RIGHT$(HEX$(S),2)  
100 PRINT #1,"("+A$+"&"+CHS$+")"  
--- Sends the data including the checksum result  
to the inverter.  
110 INPUT #1,B$  
120 PRINT "Receive data= ";B$  
130 GOTO 20  
--- Receives data returned from the inverter.  
--- Displays the data received.  
--- Repeats.  
2) Examples of program execution results  
Send Data=? R0011  
--- Reads the maximum frequency (0011).  
--- 1F40 (Maximum frequency: 80 Hz)  
--- Changes the maximum frequency to 60 Hz  
(1770).  
Receive Data= (R00111F40&3D)  
Send Data=? W00111770  
Receive Data= (W00111770&36)  
Send Data=? R0011  
Receive Data= (R00111770&31)  
--- Reads the maximum frequency (0011).  
--- 1770 (Maximum frequency: 60 Hz)  
25  
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Ex. 3 BASIC program for communication tests (RS232C, ASCII mode)  
(Toshiba version of Advanced BASIC-86 Ver. 3.01.05J)  
Accessing a parameter (with error code.)  
1) Examples of programs  
100 INPUT "Baud rate=9600/4800/2400/1200";SPEED$  
---- Selects a baud rate.  
110 INPUT "Parity=even(E)/odd(O)";PARITY$  
---- Selects parity.  
120 OPEN "COM1:"+SPEED$+","+PARITY$+",8,1"AS #1  
130 INPUT "Send data";B$  
140 PRINT #1,B$  
---- Enters a command.  
150 C$=""  
160 T=TIMER  
170 COUNT=(TIMER-T)  
180 IF COUNT >3 THEN 270  
190 IF COUNT <0 THEN T=TIMER  
200 IF LOC(1)= 0 THEN A$="":GOTO 220  
210 A$=INPUT$(1,#1)  
220 IF A$ <>CHR$(13) THEN 240  
230 GOTO 290  
---- Prevents an increase in the number of digits.  
---- Carriage return  
(CR) to finish reading in.  
240 IF A$="" THEN 160  
250 C$=C$+A$  
260 GOTO 160  
270 COLOR @0,7:PRINT "!!! There is no data to return. !!! ";:COLOR @7,0:PRINT  
280 GOTO 130  
---- Repeats.  
290 PRINT A$;  
300 C$=C$+A$  
310 PRINT "Return data=";c$;  
320 GOTO 130  
---- Repeats.  
2) Examples of program execution results (In this example, the inverter number is 00.)  
Baud rate=9600/4800/2400? 9600  
Parity=even(E)/odd(O)? E  
Send data? (00R0011)  
Return data= (00R00111770)  
Send data? ()  
---- Selects 9600 baud.  
---- Select E (even parity).  
---- Carries out test communication.  
---- Error  
!!! There is no data to return. !!!  
Send data? (R0011)  
Return data= (R00111770)  
Send data?  
---- No data is returned.  
:
:
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Ex. 4 A VisualBaisc program for the ASCII mode communication  
(VisualBaisc is the registered trademark of the U.S. microsoft company.)  
Accessing a parameter  
1) Sample program executive example (Monitor of the output frequency (FD00))  
Transmission and reception of the optional data like in the following example can be done by do-  
ing "the arrangement of the form control" of the explanation and "the description of the code" with  
mentioning later.  
Reply data from the inverter  
are 1770H (6000d) with this  
example.  
As for the unit of the output  
frequency (FD00),1= 0.01Hz,  
the Inverter is being operated  
in 60.00Hz.  
2)Arrangement of the control on the form  
Two TextBox, two Labels , three CommandButton and one MsComm are arranged on the form as  
follows.  
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3)The description of the code  
Private Sub Form_Load()  
Form1.Show  
'**********************************************************************  
' Setting the labels (Initialization)  
'**********************************************************************  
Label1.Caption = "Data for transmission"  
Label2.Caption = "Received data"  
Command1.Caption = "Transmit"  
Command2.Caption = "Clear"  
Command3.Caption = "Exit"  
'**********************************************************************  
' Setup of communication (Initialization)  
'**********************************************************************  
MSComm1.RThreshold = 0  
MSComm1.InputLen = 1  
MSComm1.CommPort = 1  
MSComm1.InBufferCount = 0  
MSComm1.OutBufferCount = 0  
Form1.MSComm1.Settings = "9600,E,8,1"  
Form1.MSComm1.InputMode = comInputModeText  
'**********************************************************************  
' A serial port is opened. (Initialization)  
'**********************************************************************  
If False = MSComm1.PortOpen Then  
MSComm1.PortOpen = True  
End If  
'**********************************************************************  
' Data are received.  
'**********************************************************************  
Do  
dummy = DoEvents()  
If MSComm1.InBufferCount Then  
Text1.Text = Text1.Text & MSComm1.Input  
End If  
Loop  
End Sub  
'**********************************************************************  
' The contents of the text box are transmitted.  
'**********************************************************************  
Private Sub Command1_Click()  
MSComm1.Output = Text2.Text & Chr(13)  
End Sub  
'**********************************************************************  
'The contents of the text box are removed.  
'**********************************************************************  
Private Sub Command2_Click()  
Text2.Text = ""  
Text1.Text = ""  
End Sub  
'**********************************************************************  
'A serial port is closed, end  
'**********************************************************************  
Private Sub Command3_Click()  
If True = MSComm1.PortOpen Then  
MSComm1.PortOpen = False  
End If  
End  
End Sub  
28  
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5. MODBUS-RTU protocol  
The MODBUS-RTU protocol of VF-AS1 supports only part of the MODBUS-RTU protocol. Only  
two commands are supported, “03: Multiple data read (limited only to two bytes)” and “06: Word  
writes.” All data will be binary codes.  
Parameter Setting  
Protocol selection (, )  
Select “MODBUSRTU (,  = ) in the communication selection parameters.  
“TOSHIBA” (, =) is set for communication protocol selection in initial shipment set-  
ting. (See “3. Communication protocol.”)  
* Caution when selecting MODBUS-RTU  
Note that selecting this protocol disables the inter-drive communication functions set with parame-  
ters  and , and the block communication functions set with parameters ,  
 and  to .  
Inverter number ()  
Inverter numbers. 0 to 247 can be specified in MODBUS-RTU. “0” is allocated to broadcast com-  
munication (no return). Set between 1 and 247.  
<Related Parameter: Change and set as necessary>  
 : Baud rate (2-wire RS485) : Communication speed (4-wire RS485)  
 : Parity (common to 2-wire RS485 and 4-wire RS485)  
Data Exchange with Inverters  
The inverters are always ready to receive messages and perform slave operation in response to  
computer requests.  
A transmission error will result if the transmission format does not match. The inverters will not re-  
spond if a framing error, parity error, CRC error or an inverter number mismatch occurs. If no re-  
sponse is received, the computer side recognizes that a communication error has occurred.  
Transmit data again.  
(1) In case spacing for more than 3.5 bytes are provided before characters, all data immediately  
preceding it will be aborted. Data will sometimes be aborted if spacing for 1.5 bytes or more is  
provided between characters. (See “3.1. About the handling of received frames.”)  
(2) Communication will be effective only when inverter numbers match or the communication mode  
is 0 (Broadcast communication). If there is no inverter number that matches or 0 (broadcast  
communication) is specified, no response is returned by any inverter.  
(3) Message reception will end if spacing for more than 3.5 bytes are provided at the end of charac-  
ters. (See “3.1. About the handling of received frames.”)  
(4) If no communication take place within the time specified using the timer function, the computer  
will assume that a communication error has occurred and trip the inverter. The timer function is  
disabled when the inverter is turned on or initialized. For details, see Section 7.3, “Timer function,  
Communication time-out time action.”  
(5) On executing the command received, the inverter returns data to the computer. For the response  
time, see Appendix 2, “Response time.”  
Caution:  
Communication is not possible for about two seconds after the power is supplied to the inverter until  
the initial setting is completed. If the control power is shut down due to an instantaneous voltage  
drop, communication is temporarily interrupted.  
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5.1. MODBUS-RTU transmission format  
MODBUS-RTU sends and receives binary data without a frame-synchronizing start code and de-  
fines the blank time to recognize the start of a frame. MODBUS-RTU decides the data that is first  
received subsequently as the first byte of a frame after a blank time for 3.5 bytes at the on-going  
communication speed.  
5.1.1. Read command (03)  
Computer Inverter *The text size is 8 bytes fixed.  
Commu- Commu- Number Number  
Inverter  
No.  
nication  
No.  
(high)  
nication  
No.  
(low)  
of Data  
Groups  
(high)  
of Data  
Groups  
(low)  
CRC  
(low)  
CRC  
(high)  
Command  
03  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
00  
01  
1) Inverter No.. (1 byte)  
: Specify an inverter number between 0 and 247 (00H to F7H).  
Command processing will be executed only broadcast communication “0” and with  
those inverters that match set inverter numbers. Data will not be returned if “0”  
(broadcast communication) and inverter numbers do not match.  
2) Command (1 byte)  
: Set the read command (03H fixed).  
3) Communication No.. (2 bytes)  
: Set in the order of high to low numbers.  
4) Number of data groups (2 bytes) : Set the number of data words 0001 (fixed) in the order of high to low numbers.  
5) CRC (2 bytes)  
: Set generation results of CRC in the order of low to high numbers.. For the  
method to generate CRC, see “5.2 CRC Generation.” Note that the setting se-  
quence is reversal to that of others.  
Inverter Computer (Normal return) *The text size is 7 bytes fixed.  
Inverter  
No.  
Number of Read data Read data  
CRC  
(low)  
CRC  
(high)  
Command  
03  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
Data  
02  
(high)  
(low)  
1) Command (1 byte)  
2) Number of data  
: Read command (03H fixed) will be returned.  
: A number of data bytes (02H fixed) will be returned. The number of data groups for  
transmission to the inverters is 2 bytes and 01H fixed. Note that the number of data re-  
turned by the inverters is 1 byte and 02H fixed.  
3) Read data (2 bytes)  
: Returned in the order of read data (high) and (low).  
Inverter Computer (Abnormal return) *The text size is 5 bytes fixed.  
CRC  
(low)  
CRC  
(high)  
Inverter No. Command Error Code  
83  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
1) Command (1 byte)  
2) Error code (1 byte)  
: 83H fixed (Read command error) (Command + 80H)  
: See “4.3 Transmission errors.”  
Example: Reading output frequency (During 60Hz operation)  
(Computer inverter)  
(Inverter computer)  
01 03 FD 00 00 01 B5 A6  
01 03 02 17 70 B6 50  
Example: Data specification error  
(Computer inverter)  
(Inverter computer)  
01 03 FD 00 00 02 F5 A7  
01 83 03 01 31  
30  
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5.1.2. Write command (06)  
Computer Inverter *The text size is 8 bytes fixed.  
Commu- Commu-  
Command nication nication  
No. (high) No. (low)  
Inverter  
No.  
Write Data Write Data  
(high) (low)  
CRC  
(low)  
CRC  
(high)  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
06  
1) Inverter No. (1 byte)  
: Specify an inverter number between 0 and 247 (00H to F7H).  
Command processing will be executed only broadcast communication “0” and with  
those inverters that match set inverter numbers. Data will not be returned if “0”  
(broadcast communication) and inverter numbers do not match.  
: Set the write command (06H fixed).  
2) Command (1 byte)  
3) Communication No. (2 bytes) : Set in the order of high to low numbers.  
4) Write data (2 bytes)  
5) CRC (2 bytes)  
: Set in the order of high to low write data.  
: Set generation results of CRC in the order of low to high numbers. For the method to  
generate CRC, see “5.2 CRC Generation.” Note that the setting sequence is rever-  
sal to that of others.  
Inverter Computer (Normal return) *The text size is 8 bytes fixed.  
Commu- Commu-  
Inverter  
No.  
Write Data Write Data  
(high) (low)  
CRC  
(low)  
CRC  
(high)  
Command nication  
nication  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
No. (high) No. (low)  
06  
: Write command (06H fixed) will be returned.  
: Returned in the order of write data (high) and (low).  
1) Command (1 byte)  
2) Write data (2 bytes)  
Inverter Computer (Abnormal return) *The text size is 5 bytes fixed.  
CRC  
(low)  
CRC  
(high)  
Inverter No. Command Error Code  
86  
(3.5bytes  
Blank)  
(3.5bytes  
Blank)  
1) Command (1 byte)  
2) Error code (1 byte)  
: 86H fixed (Read command error) (Command + 80H)  
: See “4.3 Transmission errors.”  
Example: Writing in frequency command value (FA01) (60Hz)  
(Computer inverter)  
01 06 FA 01 17 70 E6 C6  
(Inverter computer)  
01 06 FA 01 17 70 E6 C6  
Example: Communication number error  
(Computer inverter)  
01 06 FF FF 00 00 89 EE  
01 86 02 C3 A1  
(Inverter computer)  
Note  
The EEPROM life is 10,000 operations.  
Do not write in the same parameter that has an EEPROM more than 10,000 times.  
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5.2. CRC Generation  
“CRC” is a system to check errors in communication frames during data transmission. CRC is  
composed of two bytes and has hexadecimal-bit binary values. CRC values are generated by the  
transmission side that adds CRC to messages. The receiving side regenerates CRC of received  
messages and compares generation results of CRC regeneration with CRC values actually received.  
If values do not match, data will be aborted.  
Flow  
A procedure for generating a CRC is:  
CRC generation ( )  
1, Load a 16–bit register with FFFF hex (all 1’s). Call this  
the CRC register.  
CRC initial data: FFFF  
2. Exclusive OR the first 8–bit byte of the message with the  
low–order byte of the 16–bit CRC register, putting the  
result in the CRC register.  
Byte counter n = 0  
No  
Byte counter n < Length  
Yes  
3. Shift the CRC register one bit to the right (toward the  
LSB), zero–filling the MSB. Extract and examine the  
LSB.  
CRC = (CRC XOR nth send byte  
(0 expanded to word (higher 8  
bits))  
4. (If the LSB was 0): Repeat Step 3 (another shift).  
(If the LSB was 1): Exclusive OR the CRC register with  
the polynomial value A001 hex (1010 0000 0000 0001).  
Bit counter = 0  
No  
Bit counter < 8  
Yes  
5. Repeat Steps 3 and 4 until 8 shifts have been per-  
formed. When this is done, a complete 8–bit byte will  
have been processed.  
C = (Remainder of CRC ÷ 2)  
CRC >> 1  
No  
6. Repeat Steps 2 through 5 for the next 8–bit byte of the  
message. Continue doing this until all bytes have been  
processed.  
Is remainder (C)  
other than 0?  
Yes  
CRC=  
(CRC XOR generating polyno-  
mial (A001))  
7. The final contents of the CRC register is the CRC value.  
8. When the CRC is placed into the message, its upper  
and lower bytes must be swapped as described below.  
Bit counter +1  
Byte counter +1  
End (Return CRC)  
5.3. Error codes  
In case of the following errors, the return commands from the inverters are added 80h to the com-  
mands received by the inverters. The following error codes are used.  
Error Code  
01  
Description  
Command error (Returned when a command other than 03 or 06 is received)  
Communication number error (A communication number is not found when Com-  
mand 03 or 06 is received)  
02  
03  
Data range error (Data range error when Command 03 or 06 is received  
Unable to execute (Command 06 is being received and data cannot be written)  
(1) Writing in write-disable-during-operation parameter  
04  
(2) Writing in parameter that is executing TYP  
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6. Inter-drive communication  
Inter-drive communication (communication between inverters) are used, for example, when per-  
forming speed proportional control or load sharing torque control of two or more inverters without  
using a PLC or computer. The command is instructed by the operation from the master inverter’s  
panel or analog input, etc.  
With the Inter-drive communication function, the master inverter continues to transmit the data se-  
lected by the parameters to all the slave inverters on the same network. The master inverter uses  
the S command for outputting instructions to the slave inverters, and the slave inverters do not re-  
turn the data. (See chapter 4.2 "Command".) Network construction for a simple synchronized op-  
eration and speed-proportional operation can be created by this function.  
* If the master inverter trips, the slave inverters display the blinking error code “t” and come to a full  
stop (0Hz).  
Restoring the master inverter that has tripped returns the slave inverters to working order.  
* With the communication time-out parameters f803and f804, you can specify what the  
slave inverters should do (continue to operate, issue an alarm or trip) if a cable is broken or the  
master inverter is turned off during operation.  
* To use the inter-drive communication function, select “TOSHIBA Inverter Protocol” (,  
=) in the communication protocol selection parameters. “TOSHIBA Inverter Protocol”  
(, =) is set for communication protocol selection in Shipment setting. (See “3.  
Communication protocol.”)  
<Conceptual illustration>  
Slave 1 (50Hz)  
VF-AS1  
Slave 2 (40Hz)  
VF-AS1  
Slave 3 (30Hz)  
VF-AS1  
Master (60Hz)  
VF-AS1  
Analog input  
<Notes>  
Speed command can be transmitted but the run / stop signal is not issued. Slave station should have an indi-  
vidual stop signal or the function to stop the action by the frequency reference. (Setting is necessary for :  
Operation start frequency, : Operation start frequency hysteresis .)  
For continuing the operation by the last received command value in the case of a communication breakdown,  
communications time-out time () to trip the slave inverters. The master inverter does not trip even though  
the communication breakdown happens. To trip the master inverter, provide an interlock mechanism by installing  
an FL fault relay point or the like from the slave side.  
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QWiring (2-wire RS485 communication)  
Straight  
Straight  
Straight  
Slave  
Slave  
Master  
Slave  
CN1  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
Pin-4  
Pin-5  
SG  
SG  
Pin-8  
(Pin-3)  
SG  
SG  
Terminating resistance  
120Ω-1/2W  
* Never use pin-7 (P11).  
QWiring (4-wire RS485 communication))  
Straight  
Cross  
Straight  
Master  
CN1  
Slave  
RXA  
RXB  
TXA  
TXB  
SG  
Slave  
RXA  
RXB  
TXA  
TXB  
SG  
Slave  
RXA  
RXB  
TXA  
TXB  
SG  
Pin-4  
Pin-5  
Pin-3  
Pin-6  
RXA  
RXB  
TXA  
TXB  
SG  
Pin-8  
(
Pin-2)  
Terminating resistance  
120Ω-1/2W  
* Never use pin-1 (Open) and pin-7 (P11).  
* You do not need to connect the master receive lines (pins 4 and 5) or the slave send lines (pins 3  
and 6).  
34  
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E6581315  
Setting of parameter  
Protocol selection (, ) Shipment setting: 0 (TOSHIBA)  
Protocol setting with all inverters (both master and slave inverters) engaged in inter-drive commu-  
nication  
0: Set the TOSHIBA.  
* Inter-drive communication are disabled when the MODBUS-RTU protocol is selected.  
* This parameter is validated after resetting the inverter or rebooting the power supply.  
Setting of master and slave inverters for communication between inverters (setting of master and  
slave) (, ) ... Shipment setting =   
Assign one master inverter in the network. Other inverters should be the slave inverters.  
*Specify only one inverter as the master. In case two or more inverters are designated for the  
master inverter in the same network, data will collide.  
- Setting to the master inverter  
Set data desired for sending from the master side to the slave side.  
: Master (sends a frequency command)  
: Master (sends an output frequency)  
: Master (sends a torque command)  
: Master (sends an output torque command)  
- Setting to the slave inverters  
Set the desired action on the slave side that will be needed when the master trips.  
0: Slave (issues a 0Hz command if something goes wrong with the master) (when f806and  
f826are set to 3and 4, respectively.))  
(The output frequency is limited to the lower limit frequency.)  
1: Slave (continues operation if something goes wrong with the master)  
Note: If the master inverter trips when an output frequency is specified for it, the operation fre-  
quency of the slave inverters become 0Hz because tripping of the master inverter causes its  
output frequency to drop to 0Hz.  
2: Slave (trips for emergency stop if something goes wrong with the master)  
The way they make an emergency stop depends on the setting of f603(emergency stop).  
*This parameter is validated after resetting the inverter or rebooting the power supply.  
Send waiting time () ... Shipment setting =   
- Setting to the master inverter  
Specify a waiting time if you want the master to issue commands to slaves with a given delay.  
Frequency setting mode selection 1 (fm0d) ・・・ Shipment setting = 2: RR/S4 input  
Designate a target of speed command input for the inverter to the parameter .  
- Setting to the master inverter  
Select an option other than RS485 communication (fm0d5or 6).  
- Setting to the slave inverters  
Select from between:  
fm0d=5: 2-wire RS485 communication input  
fm0d=6: 4-wire RS485 communication input  
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E6581315  
Relating communication parameters  
Following parameters should be set or changed if necessary.  
Baud rate (, )... Shipment setting = : 19200bps  
Baud rate of all inverters in the network (master and slave) should be same network.  
Parity () ... Shipment setting = : Even parity  
Parity of all inverters in the network (master and slave) should be same network.  
Communication time-out time() ... Shipment setting =   
Operation is continued by the last received command value in the case of a communication break-  
down. To stop the operation of inverter, provide a communication time-out time (ex. =sec-  
ond) to the slave inverters. The master inverter does not trip even though the communication break-  
down happens. To trip the master inverter, provide an interlock mechanism by installing a FL fault  
relay point or the like from the slave side.  
Frequency point selection (, )  
Adjusted to the system.  
See chapter “6.1 Speed proportional control” for details.  
Setting example of parameters (2-wire RS485 communication)  
Parameters relating to the master side (example)  
Parameters relating to the slave side (example)  
  
  
  
Master (transmission of output frequency  
 Slave (If the master inverter trips, all slave inverters stop  
operating.)  
 Selection of communication protocol  
(Toshiba inverter protocol)  
 Communication time-out (ex. 1 second)  
 Communication baud rate (same to the master side)  
 Parity (same to the master side)  
 Terminal block (ex. Driven by F, ST)  
( Run and stop of operation is controlled with the frequency  
reference value by setting the “run frequency”.)  
(%) (100% at FH))  
Selection of communication protocol  
(Toshiba inverter protocol)  
Communication baud rate  
(ex. 19200bps)  
Parity (even parity)  
Example: Panel  
  
  
 Example: RR/S4 input  
<During torque control>  
  
 Operation panel RS485 (2-wire) communication input  
Master (sends a torque command)  
  
?  
2-wire RS485  
Adjusted to the system Point 1 setting (%)  
  
  
  
?
?
?
Ditto  
Ditto  
Ditto  
Point 2 frequency (Hz)  
Point 2 setting (%)  
Point 2 frequency (Hz)  
<During torque control>  
  
  
RS485 communication input  
Load sharing gain input mode selection (ex. Operation  
panel input enabled)  
 Panel load sharing gain (ex. Sharing of half of the com-  
mand value)  
36  
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E6581315  
6.1. Proportional control of speed  
Proportional control of frequency can be performed in two ways: control by selecting frequency  
points and control by adjusting the ratio to the maximum frequency. This section explains propor-  
tional control of inverters by means of a master inverter (inter-drive communication), although the  
AS1 series inverters are ready for proportional control by means of the “S” command even when  
they are operated under the control of a computer (computer-linked communication) (in the latter  
cases, read the master inverter as the computer).  
Proportional control can also be performed in units of Hz using ordinary write commands (W and P  
commands) (frequency point selection only). For proportional control in units of %, however, the S  
command should be used.  
* For proportional control by selecting frequency points, the gradient can be set variously according  
to the way each inverter is used. For proportional control by controlling the ratio to the maximum  
frequency, settings can be made easily without consideration of the rate at which the frequency is  
increased or decreased to the target frequency.  
Data sent by the master inverter to slave inverters in inter-drive communication mode (frequency  
command value)  
Master side fc×10000  
  fc(%)=  
      (1=0.01%)  
Master side FH  
* Fractions under 1 (0.01%) are omitted. Therefore, an error of 0.01% is introduced at the maxi-  
mum.  
Conversion of the frequency command received by a slave inverter (when the “frequency point  
selection” option is not selected)  
The value obtained by the following conversion calculation is written in RAM as a frequency com-  
mand value.  
Slavereceivedata(%)× Slave side FH  
fc( Hz ) =  
   (1=0.01Hz)  
10000  
* Fractions under 1 (0.01Hz) are omitted. Therefore, an error of 0.01Hz is introduced at the maxi-  
mum.  
[Diagram of speed proportional control]  
<Outside> <Inverter's internal computation>  
* fc=frequency reference, FH=maximum frequency  
Operation performed by the slave  
Operation performed by the  
master (or use of S command)  
(
)
Point selection   
Fc  
(Hz)  
Points not selected  
Hz  
Masterfc  
MasterFH  
%
Slave receive data  
Mastersenddata=  
×10000  
Data ( Hz )=  
× Slave FH  
10000  
Point conversion  
%
Points selected  
(Hz)  
(
)
Setting 2 fc   
Slave command  
()  
Setting 1 fc  
Point1  
()  
Point2  
()  
(%)  
Master command  
Point2fc Point1fc  
Point2Point1  
Hz  
Slavecommand=  
×( Mastercommand-Point1)+Point1fc  
fc  
SlaveFH  
Hz  
%
Data=  
×10000  
37  
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If the “Frequency point selection” function is disabled (=)  
The operation frequency (frequency command value) of the inverters are calculated using the fol-  
lowing equations, with the received data in the following equation used as the data received from  
the master inverter when inverters are operated under the control of a master inverter (inter-drive  
communication), or with the received data in the following equation used as the data received from  
the computer when inverters are operated under the control of a computer (computer-linked opera-  
tion).  
Slaverecievedata(%)× Slave side FH  
fc( Hz ) =  
   (Hz)  
10000  
Example:                
Maximum frequency Operation frequency command value  
    Unit:1=0.01Hz  
Master (Fc)  
Slave 1  
 100.00Hz (10000)  
  90.00Hz (9000)  
  80.00Hz (8000)  
50.00Hz (5000)  
45.00Hz (4500)  
40.00Hz (4000)  
Slave 2  
Master side fc ×10000 5000×10000  
Master send datafc(%) =  
=
= 5000 = 50%  
Master side FH  
10000  
5000× 9000  
Slave1: fc( Hz ) =  
= 4500 = 45Hz  
10000  
5000×8000  
Slave2 : fc( Hz ) =  
= 4000 = 40Hz  
10000  
If the “Frequency point selection” function is enabled ()  
When inverters are operated under the control of a mater inverter, the operation frequency (fre-  
quency command value) of the slave inverters are calculated using the following equations.  
When inverters are operated under the control of a computer, read “command from the master  
inverter” in the following equations as “command from the computer.”  
Point 2 frequency Point1 frequency  
fc( Hz ) =  
×Master command(%) Point1)+Point1 frequency  
Point 2 Point1  
 (Hz)  
Example:          Units: Frequency unit 1 = 0.01Hz, Point setting unit 1 = 0.01%  
Maximum  
frequency  
()  
Point 1  
setting  
()  
Point 1 fre- Point 2 set- Point 2  
Frequency  
(Fc)  
quency  
ting  
frequency  
()  
()  
()  
Master (Fc) 100.00Hz  
(10000)  
50.00Hz  
(5000)  
Slave 1  
100.00Hz  
(10000)  
0.00%  
(0)  
0.00Hz  
(0)  
100.00%  
(10000)  
90.00Hz  
(9000)  
45.00Hz  
(4500)  
Slave 2  
100.00Hz(1  
0000)  
0.00%  
(0)  
0.0Hz  
(0)  
100.00%(10  
000)  
80.00Hz  
(8000)  
40.00Hz  
(4000)  
Data sent by the master inverter  
Master side fc ×10000 5000×10000  
Master send data : fc(%) =  
=
= 5000 = 50%  
Master side FH  
10000  
Both slaves 1 and 2: Result of a conversion made on the slave side  
Slavereceivedata(%)× Slave side FH 5000×10000  
fc( Hz ) =  
=
= 5000 = 50Hz  
10000  
10000  
Both slaves 1 and 2: Result of a conversion to % made prior to a conversion to point frequency  
fc( Hz )×10000 5000×10000  
fc(%) =  
=
= 5000 = 50%  
Slaveside FH  
10000  
Results of conversions to point frequency (for the equation used, see above.)  
9000 0  
10000 0  
8000 0  
Slave1: fc( Hz ) =  
×(5000 0 )0 = 4500 = 45Hz     
Slave2 : fc( Hz ) =  
×(5000 0)0 = 4000 = 40Hz  
10000 0  
38  
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E6581315  
6.2. Transmission format for inter-drive communication  
Data type is handled in hexadecimal notation and the transmission characters are treated with the  
binary (HEX) code.  
The transmission format is basically the same to the case of binary mode. S command is used and  
the slave inverters do not return the data.  
Master inverter Slave inverter (Binary mode)  
Omissible  
(3.5bytes  
Blank) (2FH)  
“/”  
INV-NO  
1 byte  
CMD  
1 byte  
Communication No.  
2 bytes  
DATA  
2 bytes  
SUM  
1 byte  
(3.5bytes  
Blank)  
            
 
Checksum area  
        Not omissible  
1) INV-NO (1 byte)  
: Inverter number  
This is always excluded at the master inverter side at time of inter-drive communication, and  
can be added when the user utilize this data for the purpose of proportional operation.  
(When this code is added, only the inverter concerned will accept the data.)  
: Command  
2) CMD (1 byte)  
53H(“S”) or 73(“s”) command ... command for inter-drive communication  
When the master inverter is not tripping, this will be 53H(“S”).  
When the master inverter is tripping, this will be 73H(“s”).  
3) Communication number (2 bytes)  
:
Specify “FA01” for two-wire RS485 communication.  
Specify “FA05” for four-wire RS485 communication.  
: Data of frequency command value.  
4) DATA (2 bytes)  
(0000H to FFFFH (no range check))  
As for the S command, see section 4.2 “Commands”, and see chapter “6 Inter-drive communication function” for the  
communication of inverters.  
39  
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E6581315  
7. Communication parameters  
The settings of communication-related parameters can be changed from the operation panel and  
the external controller (computer). Note that there are two types of parameters: parameters whose  
settings take effect immediately after the setting and parameters whose settings do not take effect  
until the inverter is turned back on or reset.  
Com-  
munica-  
tion  
Default  
setting  
Title  
Function  
Adjustment range  
Unit  
-
Valid  
Reference  
Section 7.1  
Number.  
0: 9600bps  
Baud rate  
(2-wire RS485)  
0800  
1: 19200bps  
2: 38400bps  
0: Non parity  
1: Even parity  
2: Odd parity  
1
After reset.  
  
0801  
0802  
0803  
Parity (common)  
-
1
0
0
After reset.  
Real time  
Real time  
Section 7.1  
Section 7.2  
Section 7.3  
  
  
  
Inverter number  
(common)  
Communication  
time-out time  
(common)  
0-247  
1
0:OFF  
1-100s  
1s  
2-wire  
4-wire  
0
1
2
3
4
5
6
7
8
-
-
-
-
t alarm  
Err5 trip  
-
t alarm  
Err5 trip  
-
Communication  
time-out action  
(common)  
t alarm  
t alarm  
t alarm  
Err5 trip  
Err5 trip  
Err5 trip  
0804  
0805  
1
8
Real time  
Real time  
Section 7.3  
Section 7.4  
  
  
t alarm  
Err5 trip  
Send waiting time 0.00: Default  
(2-wire RS485) 0.01-2.00s  
0.01s  
0.00  
0:Slave (issues a 0Hz command if some-  
thing goes wrong with the master)  
1:Slave (continues operation if something  
goes wrong with the master)  
Inverter-to-inverter 2:Slave (trips for emergency stop if  
0806  
communication (2-  
wire RS485)  
something goes wrong with the master)  
3:Master (sends a frequency command)  
4:Master (sends an output frequency)  
5.Master (sends a torque command)  
6.Master (sends an output torque com-  
mand)  
-
0
After reset.  
  
Chapter 6  
Protocol selection 0: TOSHIBA  
0807  
0810  
-
-
0
0
After reset.  
Real time  
  
  
Chapter 3  
(2-wire RS485)  
1:MODBUS-RTU  
0:Disabled  
Frequency point  
selection  
1:2-wire RS485  
2:4-wire RS485  
Section 6.1  
3:Communication add option  
0811  
0812  
0813  
0814  
Point 1 setting  
0-100%  
-
0
Real time  
Real time  
Real time  
Real time  
  
  
  
  
Point 1 frequency 0-Hz  
Point 2 setting 0-100%  
Point 2 frequency 0-Hz  
0.01Hz  
-
0.0  
Section 6.1  
100  
60.0  
0.01Hz  
Communication  
speed  
(4-wire RS485)  
Send waiting time 0.00: Normal  
(4-wire RS485) 0.01-2.00s  
0: 9600bps  
1: 19200bps  
2: 38400bps  
0820  
0825  
-
1
After reset.  
Real time  
Section 7.1  
Section 7.4  
  
  
0.01s  
0.00  
40  
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E6581315  
Reference  
Com-  
munica-  
tion  
Default  
setting  
Title  
Function  
Adjustment range  
Unit  
Valid  
Number.  
0:Slave (issues a 0Hz command if some-  
thing goes wrong with the master)  
1:Slave (continues operation if something  
goes wrong with the master)  
2:Slave (trips for emergency stop if  
something goes wrong with the master)  
3:Master (sends a frequency command)  
4:Master (sends an output frequency)  
5.Master (sends a torque command)  
6.Master (sends an output torque com-  
mand)  
Inverter-to-inverter  
communication  
setting (4-wire  
RS485)  
0826  
-
0
After reset.  
  
Chapter 6  
Chapter 3  
Protocol selection 0: TOSHIBA  
0829  
0870  
-
-
0
0
After reset.  
After reset.  
  
  
(4-wire RS485)  
1: MODBUS-RTU  
0: Deselect  
Block write data 1  
1: Command information 1 (FA00)  
2: Command information 2 (FA20)  
3: Frequency command (FA01)  
4: Terminal board output data  
(FA50)  
Section  
4.1.3  
0871  
Block write data 2  
  
5: Communication analog data  
(FA51)  
0: Deselect  
0875  
0876  
0877  
0878  
Block read data 1  
Block read data 2  
Block read data 3  
Block read data 4  
  
  
  
  
1: Status information (FD01)  
2: Output frequency (FD00)  
3: Output current (FD03)  
4: Output voltage (FD05)  
5: Alarm information (FC91)  
6: PID feedback value (FD22)  
7: Input terminal board monitor (FD06)  
8: Output terminal board monitor (FD07)  
9: VI/IIterminal board monitor (FE36)  
10: RR/S4 terminal board monitor (FE35)  
11:RX terminal board monitor (FE37)  
12:Input voltage (DC detection) (FD04)  
13:Speed feedback frequency (FD16)  
14:Torque (FD18)  
Section  
4.1.3  
-
0
After reset.  
0879  
0880  
Block read data 5  
  
  
15:MY monitor 1 (FE60)  
16:MY monitor 2 (FE61)  
17:MY monitor 3 (FE62)  
18:MY monitor 4 (FE63)  
19:Free notes (F880)  
Free notes  
0-65535  
1
0
Real time  
Section 7.5  
41  
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7.1. Baud rate(, ) , Parity ()  
Communication baud rate and parity bit should be uniform inside the same network.  
This parameter is validated by resetting the power supply.  
7.2. Inverter number()  
This parameter sets individual numbers with the inverters.  
Inverter numbers should not be duplicate inside the same network.  
Receiving data will be canceled if inverter numbers specified in individual communication and set by  
a parameter do not match.  
This parameter is validated from the communication after change  
Data range: 0 to 247 (Initial value: 0)  
Parameters can be selected between 0 and 247. Note that the communication protocols limit in-  
verter numbers as follows:  
TOSHIBA Inverter Protocol ASCII mode: 0 to 99  
TOSHIBA Inverter Protocol Binary mode: 0 to 63  
MODBUS Protocol: 0 to 247 (0: Broadcast communication)  
42  
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7.3. Communication time-out time (), Communication time-out action (f804)  
The timer function is mainly used to detect a break in a cable during communication, and if no data  
is sent to an inverter within the preset time, this function makes the inverter trip () or issue  
an alarm (). With the communication time-out action parameter (), you can specify what  
the inverter should do (trip, issue an alarm or do nothing) if a time-out occurs.  
How to set the timer  
By default, the communication time-out time parameter () is set to (OFF).  
* Timer adjustment range  
About 1 sec. (01H) to about 100 sec. (64H) / Timer off (0H)  
How to specify what an inverter should do if a time-out occurs  
By default, the communication time-out action parameter () is set to ( trip) for both  
2-wire and 4-wire RS485 communication.  
* Selection of time-out action (Range: 0 to 8 ... For details refer to “6. Communication parameters.)  
The action of the inverter at the occurrence of a time-out can be selected from among “do noth-  
ing,” “trip ()” and “alarm ()” individually for two-wire and four-wire RS485 communica-  
tion.  
How to start the timer  
If the timer is set from the operation panel, it will start automatically the instant when communication  
is established for the first time after the setting.  
If the timer is set from the computer, it will start automatically the instant when communication is  
established after the setting.  
If the timer setting is stored in the EEPROM, the timer will start when communication is established  
for the first time after the power has been turned on.  
Note that, if the inverter number does not match or if a format error occurs, preventing the inverter  
from returning data, the timer function will assume that no communication has taken place and will  
not start.  
How to disable the timer  
To disable the timer, set its parameter to 0.  
Ex.: To disable the timer function from the computer (To store the timer setting in the EEPROM)  
Computer Inverter  
Inverter Computer  
(W08030)CR  
(W08030000)CR  
... Sets the timer parameter to 0 to disable it.  
Timer  
Time-out period  
The timer measures the time  
elapsed before the inverter ac-  
knowledges receipt of data after it  
acknowledged receipt of the previ-  
ous data.  
Computer link  
PC INV  
PC INV  
INV PC  
Master INV  
to Slave  
INV  
Master INV  
to Slave  
INV  
Inter-drive  
communication  
43  
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E6581315  
7.4. Send waiting time (, )  
Use this function for the following case:  
When the data response from the inverter is too quick after the PC had sent the data to the inverter,  
PC process cannot get ready to receive the data, or when the USB/RS485, RS485/RS232C con-  
verter is used, changeover of sending and receiving data takes much time in the converter process.  
Functional specification:  
A time for sending data is prolonged longer than the preset time (, ), until the inverter  
returns the data to the PC, after it finishes receiving the data (in case of an inter-drive communica-  
tion, until the inverter returns the next data to the PC, after it has sent the data.) In case the inverter's  
processing capacity requires longer setting time, the value more than this time will be the set value.  
(The parameter makes the inverter wait for more than the set time.)  
Setting range:  to seconds (10ms to 2000ms)  
If the set value is , this function becomes invalid and the interval time for sending data is set to the  
maximum capacity of the inverter. To obtain a quick response for sending data, set value .  
Time elapses more than  
transmission waiting time.  
Computer link  
PC INV  
INV PC  
Inter-drive  
Master INV  
communication  
to Slave INV  
Master INV to  
Slave INV  
Time elapses more than the  
transmission waiting time.  
7.5. Free notes()  
This parameter allows you to write any data, e.g., the serial number of each inverter or parameter  
information, which does not affect the operation of the inverter.  
44  
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8. Commands and monitoring from the computer  
Across the network, instructions (commands and frequency) can be sent to each inverter and the  
operating status of each inverter can be monitored.  
8.1. Communication commands (commands from the computer)  
Communication command (Communication number: FA00, FA04)  
Commands can be executed on inverter frequencies and operation stop through communication.  
The VF-AS1 series can enable command and frequency settings through communication irrespec-  
tive of settings of the command mode selection () and frequency setting mode selection 1  
(). However, if “48 (49): Forced switching from communication to local,” “56 (57): Forced  
continuous operation,” or “58 (59): Specified speed operationj” is set by input terminal function se-  
lection ( to ), a change to a command other than communication and to a frequency  
command is feasible through a contact on the terminal board.  
Once the communication command (FA00, FA04) is set to enable communication command priority  
and frequency priority, both priorities will be enabled unless OFF is set, power is turned off or is re-  
set, or factory default setting () is selected. Emergency stop is always enabled even though  
communication command priority is not set.  
Table 1 Data construction of communication commands (communication number: FA00, FA04)  
bit Specifications  
0
1
Remarks  
0
1
2
3
4
Preset speed operation Preset speed operation is disabled or preset  
frequencies 1  
speed operation frequencies (1-15) are set by  
specifying bits for preset speed operation frequen-  
cies 1-4.  
Preset speed operation  
frequencies 2  
(0000: Preset speed operation OFF,  
001-1111: Setting of preset speed operation  
frequencies (1-15))  
Preset speed operation  
frequencies 3  
Preset speed operation  
frequencies 4  
Motor selection (1 or 2)  
(THR 2 selection)  
PI control  
Motor 1  
(THR 1)  
Motor2  
(THR2)  
THR1 :   
THR2 :   
5
6
Normal operation  
Accelera-  
PI OFF  
Acceleration/deceleration  
Accelera-  
AD1 : ,   
pattern selection (1 or 2) tion/deceleration pattern tion/deceleration pattern AD2 : ,   
(AD2 selection)  
DC braking  
1 (AD1)  
OFF  
2 (AD2)  
Forced DC braking  
Jog run  
7
8
9
Jog run  
OFF  
Forward/reverse run se-  
lection  
Forward run  
Reverse run  
10 Run/stop  
Stop  
Standby  
OFF  
Run  
Coast stop  
Emergency stop  
Reset  
11 Coast stop command  
12 Emergency stop  
13 Fault reset  
Always enabled, “E” trip  
No data is returned from the inverter.  
Enabled regardless of the set-  
ting of   
OFF  
14 Frequency priority selec-  
tion  
OFF  
Enabled  
15 Command priority selec-  
tion  
OFF  
Enabled  
Enabled regardless of the set-  
ting of   
Note: The acceleration/deceleration change command OR with Bit 8 and 9 of Communication num-  
ber FA20 and FA22.  
Ex.: Forward run command used in two-wire RS485 communication (PFA008400) CR  
1 is specified for bit 15 (communication command: enabled) and bit 10 (operation command).  
BIT15  
BIT0  
FA00:  
1
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
8
4
0
0
Ex.: Reverse run command used in two-wire RS485 communication (PFA008600) CR, (PFA00C600) CR  
8600H : To disable frequency instructions from the computer  
C600H : To enable also frequency instructions from the computer  
45  
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Communication command2 (Communication Number : FA20, FA22)  
This command is enabled only when the communication command is enabled. Set Bit 15 of Com-  
munication Command 1 (communication Number: FA00, FA04) to “1” (enable). When enabling the  
communication command by Communication Command 1, commands by communication can be  
given the priority irrespective of the setting of the command mode selection parameter ().  
However, if “48 (49): Forced switching from communication to local,” “56 (57): Forced continuous  
operation,” or “58 (59): Specified speed operationj” is set by input terminal function selection  
( to ), the enabled command and frequency will be given the priority.  
Once enabled, this setting will be enabled till disable is set (0 setting), power is turned off or is reset,  
or factory default setting () is selected.  
Table 2 Data construction of communication command 2 (FA20, FA22)  
Bit  
Function  
0
1
Remarks  
0
Control switching  
electric power quantity  
reset  
Speed control  
Torque control  
Electric power quantity  
(FE76, FE77) reset  
1
OFF  
Reset  
2
3
4
5
6
(Reserved)  
Normal  
Normal  
Forcibly braked  
Enabled  
Brake released  
Brake released  
Braking request (BC)  
Preliminary excitation  
Brake release (B)  
Braking answer (BA)  
Brake applied  
Brake applied  
Maximum  
deceleration  
7
8
Normal  
Enabled  
forced stop  
Acceleration/deceleration  
pattern selection 1  
Select Acceleration/ de-  
celeration 1 - 4 by combi-  
nation of two bits  
00: Acceleration/deceleration 1  
01: Acceleration/deceleration 2  
10: Acceleration/deceleration 3  
11: Acceleration/deceleration 4  
AD1: ,   
Acceleration/deceleration  
pattern selection 2  
AD2: ,   
AD3: ,   
AD4: ,   
9
00: V/F 1  
01: V/F 2  
10: V/F 3  
11: V/F 4  
10  
11  
12  
13  
V/Fswitching 1  
Select V/F 1 - 4 by combi-  
nation of two bits  
V/Fswitching 2  
00: Torque limit 1  
01: Torque limit 2  
10: Torque limit 3  
11: Torque limit 4  
Torque limit switching 1  
Torque limit switching 2  
Select torque limit 1 - 4 by  
combination of two bits  
Gain 1: ,   
Gain 2: ,   
14  
15  
Speed gain 1/2  
(Reserved)  
Gain 1  
Gain 2  
Note: The acceleration/deceleration change command ORs with Bit 6 of Communication number  
FA00 and FA04.  
Set Bit 6 of FA00 and FA04 to “0” and use FA20 and FA22 when changing acceleration/deceleration  
in four types. Acceleration/deceleration 4 will be set when both Bit 8 of Communication number  
FA20 and FA22 (or Bit 6 of Communication number FA00 and FA04) and Bit 9 of Communication  
number FA20 and FA22 are set.  
46  
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Frequency setting from the computer “Communication Number: FA01, FA05”  
Setting range: 0 to maximum frequency (fh)  
This frequency command is enabled only when the frequency command by communication is en-  
abled. To make frequency commands from the computer valid, set the frequency setting mode se-  
lection parameter (fmod) to RS485 communication (communication No. 0004: 5 (2-wire RS485  
communication input) or 6 (4-wire RS485 communication input) or select the “Command priority”  
option (bit 14 of FA00 and FA04: 1 (enabled)). In this case, frequency commands by communica-  
tion will be enabled independent of fmodsetting.  
However, enabled commands and frequencies are given the priority if “48 (49): Forced switching  
from communication to local,” “56 (57): Forced continuous operation,” or “58 (59): Specified speed  
operation” is set by input terminal function selection (f11oto f118).  
Once enabled, this frequency setting will be enabled till disable is set (0 setting), power is turned off  
or is reset, or factory default setting (typ) is selected.  
Set a frequency by communication hexadecimal in Communication Number FA01, FA05.  
(1=0.01Hz (unit))  
Example: Operation frequency 80Hz command by 2-wire RS485 communication (PFA011F40) CR  
80Hz=80÷0.01=8000=1F40H  
Torque command setting from the computer “2-wire RS485 communication: FA30,  
4-wire RS485 communication: FA32  
This section explains how to set a torque command value for inverters. The torque command value  
set here takes effect if torque commands from the computer are valid when the inverters are in tor-  
que control mode (in cases where torque control is selected with the terminal board or with a com-  
munication command when ( is set to 4 or 8).  
To make torque commands from the computer valid, set the torque command selection parameter  
 (communication No. 0420) to 5 (2-wire RS485 communication input) or 6 (4-wire RS485  
communication input). Once torque commands from the computer have been set, they remain valid  
until they are changed, the inverters is turned off or reset, or the parameter  for returning set-  
tings to their defaults is selected. (The settings of FA30 and FA32 are not stored in EEPROM.  
Therefore, they are cleared when the inverter is turned off or reset.)  
When setting a torque for torque commands from the computer, specify a torque in hexadecimal  
(unit: 1=0.01%, two-wire RS485 communication: FA30 or four-wire RS485 communication: FA32).  
Example: 50% torque command (PFA321388)  
50%=50÷0.01=5000=1388H  
47  
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Terminal board output data (FA50)  
The output terminal board on each inverter can be directly controlled with the computer.  
To use this function, select functions 92 to 105 in advance for the output terminal function selection  
parameters f130to f138, f168andf169. If bit 0 through bit 6 of terminal board  
output data (FA50) are set with the computer, data specified (0 or 1) can be sent to any output ter-  
minal.  
Data composition of terminal board output data (FA50)  
Bit  
0
Output terminal function  
Specified data output 1  
0
1
OFF  
ON  
(Output terminal no.: 92, 93)  
Specified data output 2  
(Output terminal no.: 94, 95)  
Specified data output 3  
(Output terminal no.: 96, 97)  
Specified data output 4  
(Output terminal no.: 98, 99)  
Specified data output 5  
(Output terminal no.: 100, 101)  
Specified data output 6  
(Output terminal no.: 102, 103)  
Specified data output 7  
(Output terminal no.: 104, 105)  
1
OFF  
OFF  
OFF  
OFF  
OFF  
OFF  
ON  
ON  
ON  
ON  
ON  
ON  
2
3
4
5
6
7 to 15  
Example of use: To control only the OUT1 terminal with the computer  
To turn on the OUT1 terminal, set the output terminal function selection 1 parameter  
(f130) to 92 (output terminal function selection 1 (positive logic)) and specify 0001H for  
FA50.  
           
FA50:  
BIT15  
BIT0  
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
FM analog output (FA51)  
The FM analog terminal on each inverter can be directly controlled with the computer.  
To use this function, set the FM terminal meter selection parameter (fmsl) to 31 (communication  
data output).  
This makes it possible to send out the data specified as FM analog output data (FA51) through the  
FM analog output terminal. Data can be adjusted in a range of 0 to 2047 (resolution of 11 bits).  
For details, refer to “Meter setting and adjustment” of the instruction manual included with the  
inverter.  
AM analog output (FA52)  
The AM analog terminal on each inverter can be directly controlled with the computer.  
To use this function, set the AM terminal meter selection parameter (amsl) to 31 (communication  
data output).  
This makes it possible to send out the data specified as AM analog output data (FA52) through the  
AM analog output terminal. Data can be adjusted in a range of 0 to 2047 (resolution of 11 bits).  
For details, refer to “Meter setting and adjustment” of the instruction manual included with the  
inverter.  
48  
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8.2.Monitoring from the computer  
This section explains how to monitor the operating status of the inverter from the computer.  
Monitoring of the output frequency from the computer (FD00, FE00)  
Output frequency (current status): “Communication Number FD00” (minimum unit: 0.01Hz)  
Output frequency (status immediately before the occurrence of a trip): “Communication Number  
FE00” (minimum unit: 0.01Hz)  
The current output frequency is read out in hexadecimal in units of 0.01Hz. For example, if the out-  
put frequency is 80Hz, 1F40H (hexadecimal number) is read out. Since the minimum unit is 0.01Hz,  
1F40H (hexadecimal number) = 8000 (decimal number) x 0.01 = 80 (Hz)  
Example: Monitoring of the output frequency (operation frequency: 50Hz) ・・・ (1F40H=8000d,  
8000×0.1=80Hz)  
 ComputerInverter  InverterComputer  
(RFD00)CR  
   (RFD001F40)CR  
The following items are also calculated in the same way.  
• FD22 (PID feedback value).................................Unit: 0.01Hz  
• FD16 (speed feedback) ......................................Unit: 0.01Hz  
• FD29 (input power) .............................................Unit: 0.01kW  
• FD30 (output power) ...........................................Unit: 0.01kW  
Monitoring of the output current with the computer (FD03, FE03)  
Output current (current status): “Communication Number FD03” (minimum unit: 0.01Hz)  
Output current (status immediately before the occurrence of a trip): “Communication Number FE03”  
(minimum unit: 0.01Hz)  
The current output current is read out in hexadecimal in units of 0.01%. For example, if the output  
current of an inverter with a current rating of 4.8A is 2.4A (50%), 1388H (hexadecimal number) is  
read out. Since the minimum unit is 0.01%, 1388H (hexadecimal number) = 5000 (decimal number)  
x 0.01 = 50 (%)  
Example: Monitoring of the output current (output current: 90%) ・ ・ ・ (2328H=9000d,  
9000×0.01=90%)  
 ComputerInverter  InverterComputer  
(FRD03)CR  
   (RFD032328)CR  
The following items are also calculated in the same way.  
• FD05 (output voltage) .........................................Unit: 0.01% (V)  
• FD04 (DC voltage) ..............................................Unit: 0.01% (V)  
• FD18 (torque)......................................................Unit: 0.01% (N·m) *  
* If data on the motor connected to the inverter is entered with parameters f405to f415,  
100% of the monitored torque closely agrees with the rated torque of the motor.  
49  
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Input terminal board status (FD06, FE06)  
Input terminal board status (current status): “Communication Number FD06”  
Input terminal board status (status immediately before the occurrence of a trip): “Communication  
Number FE06”  
Using terminal function selection parameters, functions can be assigned individually to the termi-  
nals on the input terminal board.  
If a terminal function selection parameter is set to 0 (no function assigned), turning on or off the cor-  
responding terminal does not affect the operation of the inverter, so that you can use the terminal as  
you choose.  
When using a terminal as a monitoring terminal, check beforehand the function assigned to each  
terminal.  
Data composition of input terminal board status (FD06, FE06)  
Bit  
0
Terminal name  
Function (parameter title)  
0
1
F
Input terminal function selection 1 (f111)  
Input terminal function selection 2 (f112)  
Input terminal function selection 3 (f113)  
Input terminal function selection 4 (f114)  
Input terminal function selection 5 (f115)  
Input terminal function selection 6 (f116)  
Input terminal function selection 7 (f117)  
Input terminal function selection 8 (f118)  
Input terminal function selection 9 (f119)  
Input terminal function selection 10 (f120)  
Input terminal function selection 11 (f121)  
Input terminal function selection 12 (f122)  
Input terminal function selection 13 (f123)  
Input terminal function selection 14 (f124)  
Input terminal function selection 15 (f125)  
Input terminal function selection 16 (f126)  
1
R
2
ST  
RES  
S1  
S2  
S3  
S4  
L1  
L2  
L3  
L4  
L5  
L6  
L7  
L8  
3
4
5
6
7
OFF  
ON  
8
9
10  
11  
12  
13  
14  
15  
Example: Data set for FE06 when the F and S1 terminals are ON = 0011H  
BIT15 bit0  
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
1
FE06:  
0
0
9
0
50  
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Output terminal board status (FD07, FE07)  
Output terminal board status (current status): “Communication Number FD07”  
Output terminal board status (status immediately before the occurrence of a trip): “Communication  
Number FE07”  
Using terminal function selection parameters, functions can be assigned individually to the termi-  
nals on the output terminal board.  
When using a terminal as a monitoring terminal, check beforehand the function assigned to each  
terminal.  
Data composition of output terminal board status (FD07, FE07)  
Bit  
Terminal name  
Function (parameter title)  
Output terminal function selection 1 (f130)  
Output terminal function selection 2 (f131)  
Output terminal function selection 3 (f132)  
Output terminal function selection 4 (f133)  
Output terminal function selection 5 (f134)  
Output terminal function selection 6 (f135)  
Output terminal function selection 7 (f136)  
Output terminal function selection 8 (f137)  
Output terminal function selection 9 (f138)  
Output terminal function selection 10 (f168)  
Output terminal function selection 11 (f169)  
0
1
0
OUT1  
OUT2  
FL  
1
2
3
OUT3  
OUT4  
R1  
4
5
OFF  
ON  
6
OUT5  
OUT6  
R2  
7
8
9
R3  
10  
R4  
11 to 15  
Example: Data set for FE07 when both the OUT1 and OUT2 terminals are ON = 0003H  
BIT15 bit0  
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
FE07:  
0
0
3
0
Monitoring of the analog input with the computer (FE35 to FE39)  
RR terminal board monitor: “Communication Number FE35”  
VI/II terminal board monitor: “Communication Number FE36”  
RX terminal board monitor: “Communication Number FE37”  
AI1 terminal board monitor : “Communication Number FE38”  
AI2 terminal board monitor: “Communication Number FE39”  
These monitors can also be used as A/D converters irrespective of the inverter’s control.  
RR terminal board monitor, VI/II terminal board monitor and AI2 terminal board monitor are capable  
of reading the data from external devices in a range of 0.01 to 100.00% (unsigned data: 0H to  
2710H).  
RX terminal board monitor and AI1 terminal board monitor are capable of reading the data from ex-  
ternal devices in a range of -100.00 to +100.00% (signed data: D8F0H to 2710H).  
If analog input mode is selected with the frequency setting mode selection parameter, however,  
keep in mind that any data entered via an analog terminal is regarded as a frequency command.  
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Inverter operating status 1 (FD01, FE01)  
Inverter status 1 (current status): Communication Number FD01  
Inverter status 1 (status immediately before the occurrence of a trip): Communication Number FE01  
Bit Specifications  
0
1
Remarks  
0
1
Failure FL  
Failure  
No output  
Not tripped  
Output in progress  
Tripped  
Trip statuses include   
and trip retention status.  
2
3
4
Alarm  
No alarm  
-
Alarm issued  
Reserved  
-
Motor section (1 or 2) Motor 1 (THR 1)  
(THR 2 selection)  
Motor 2 (THR 2)  
5
6
PI control OFF  
PI control  
permitted  
PI control  
prohibited  
Accelera-  
tion/deceleration  
Acceleration/  
deceleration  
Acceleration/  
deceleration pat- AD2 :,   
AD1 :,   
pattern selection (1 or pattern 1 (AD 1)  
2)  
tern 2 (AD 2)  
7
8
9
DC braking  
OFF  
OFF  
Forced DC braking  
Jog run  
Jog run  
Forward/reverse run  
Forward run  
Stop  
Reverse run  
Run  
10 Run/stop  
11 Coast stop (ST=OFF)  
12 Emergency stop  
ST=ON  
ST=OFF  
Not emergency  
stop status  
Start-up process  
Emergency stop  
status  
13 Standby ST=ON  
Standby  
Standby: Initialization completed,  
not failure stop status, not alarm  
stop status (MOFF, LL forced  
stop or forced stop due to a  
momentary  
power  
failure),  
ST=ON, and RUN=ON  
14 Standby  
Start-up process  
Standby  
Standby: Initialization completed,  
not failure stop status, and not  
alarm stop status (MOFF, LL  
forced stop or forced stop due to  
a momentary power failure)  
15 Reserved  
-
-
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Inverter operating status 2 (FD42, FE42)  
Inverter status 2 (current status): Communication Number FD42  
Inverter status 2 (status immediately before the occurrence of a trip): Communication Number FE42  
Bit  
0
Function  
0
1
Remarks  
Control mode switching  
Speed control  
(Simple posi-  
tioning)  
Torque control  
1
Electric Power Counting  
(FE76,FE77) status  
(Reserved)  
Counting  
Resetting  
2
3
4
5
6
7
-
-
(Reserved)  
-
-
Preliminary excitation  
(Reserved)  
Normal  
Operation  
-
-
(Reserved)  
-
-
Maximum deceleration forced  
stop  
Normal  
Operation  
8
9
Acceleration/deceleration  
pattern selection1  
Acceleration/deceleration  
00:Acceleration/deceleration 1 Acceleration/ decelera-  
01:Acceleration/deceleration 2 tion 1 - 4 can be specified  
10:Acceleration/deceleration 3 by combination of two  
11:Acceleration/deceleration 4 bits  
pattern selection2  
V/Fswitching 1  
Select V/F 1 - 4 by com-  
bination of two bits  
00: V/F 1  
01: V/F 2  
10: V/F 3  
11: V/F 4  
10  
11  
V/Fswitching 2  
Torque limit switching 1  
Torque limit switching 2  
00: Torque limit 1  
01: Torque limit 2  
10: Torque limit 3  
11: Torque limit 4  
Gain 1  
Select torque limit 1 - 4  
by combination of two  
bits  
12  
13  
Speed gain 1/2  
(Reserved)  
Gain 2  
-
Gain 1: ,   
Gain 2: ,   
14  
15  
-
Inverter operating status 3 (FD49, FE49)  
Inverter status 3 (current status): Communication Number FD49  
Inverter status 3 (current status): Communication Number FE49  
Bit  
Function  
0
1
Remarks  
0 to 11 (Reserved)  
-
-
Not achieved  
Achieved  
Related parameters  
12  
Acceleration/deceleration  
completion (RCH)  
f102  
Not achieved  
-
Achieved  
-
Related parameters  
13  
Specified speed reach (RCHF)  
f101, f102  
14 to 15 (Reserved)  
53  
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E6581315  
Inverter operating command mode status (FD45, FE45)  
The monitor of the command mode that the present condition is enabled  
Command mode status (current status): “Communication Number FD45”  
Command mode status (status immediately before the occurrence of a trip): “Communication Num-  
ber  
Data  
Enabled command  
0
1
2
3
4
Terminal input enabled  
Operation panel input enabled  
Operation panel RS485 (2-wire) communication input  
Internal RS485 (4-wire) communication input  
Communication option input  
Inverter operating frequency mode status (FD46, FE46)  
The monitor of the frequency command mode that the present condition is enabled  
Note that Preset speed operation frequencies is given the priority independent of the frequency  
mode, in which case this monitor will be disabled, in case Preset speed operation frequencies is  
selected.  
Frequncy mode status (current status): Communication Number FD46  
Frequncy mode status (status immediately before the occurrence of a trip): Communication  
Number FE46  
Data  
1
Enabled frequency  
VI/II input  
2
RR/S4 input  
3
RX input  
4
Operation panel input enabled  
Operation panel RS485 (2-wire) communication input  
Internal RS485 (4-wire) communication input  
Communication option input  
Optional AI1  
5
6
7
8
9
Optional AI2  
10  
11  
12  
13  
255  
UP/DOWN frequency  
RP pulse input  
High-speed pulse input  
Binary/BCD input  
Preset speed operation  
54  
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E6581315  
Alarm information monitor (FC91)  
Remarks  
Bit  
Specifications  
Over-current alarm  
0
1
(Code displayed on the panel)  
0
1
Normal  
Normal  
Normal  
Normal  
Normal  
Normal  
-
Alarming  
Alarming  
Alarming  
Alarming  
Alarming  
Alarming  
-
 flickering  
 flickering  
Inverter overload alarm  
Motor overload alarm  
Overheat alarm  
 flickering  
 flickering  
 flickering  
2
3
4
Overvoltage alarm  
Main circuit undervoltage alarm  
(Reserved)  
5
-
-
-
-
-
-
6
7
Low current alarm  
Normal  
Normal  
Normal  
Normal  
Alarming  
Alarming  
Alarming  
Alarming  
8
Over-torque alarm  
Braking resistor overload alarm  
9
Cumulative operation hours  
alarm  
10  
11 (Reserved)  
12 (Reserved)  
13 (Reserved)  
-
-
-
-
-
-
-
-
-
-
At the time of the instant black-  
Decelerating, Related:  setting  
stopping  
Decelerating, Related:  setting  
stopping  
14  
out, Forced deceleration/stop  
An automatic stop during the  
lower limit frequency continu-  
ance  
15  
-
Cumulative operation time alarm monitor (FE79)  
Bit  
0
Specifications  
Fan life alarm  
0
1
Remarks  
Normal  
Normal  
Normal  
Normal  
-
Alarm issued  
Alarm issued  
Alarm issued  
Alarm issued  
-
-
-
-
-
-
1
Circuit board life alarm  
Main-circuit capacitor life alarm  
User set alarm  
2
3
4-15 (Reserved)  
55  
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E6581315  
Trip code monitor (current status: FC90: historic records: FE10 to FE13)  
Data  
Data  
(hexadeci-  
mal number)  
(decimal  
number)  
Code  
Description  
0
1
0
No error  
nerr  
oc1  
1
2
3
4
5
6
7
8
9
Over-current during acceleration  
Over-current during deceleration  
Over-current during constant speed operation  
Over-current in load at startup  
U-phase arm overcurrent  
2
oc2  
3
oc3  
4
ocl  
5
ocai  
oca2  
oca3  
ephi  
epho  
op1  
6
V-phase arm overcurrent  
7
W-phase arm overcurrent  
8
Input phase failure  
9
Output phase failure  
A
10 Overvoltage during acceleration  
11 Overvoltage during deceleration  
12 Overvoltage during constant speed operation  
13 Over-LOAD in inverter  
14 Over-LOAD in motor  
15 Dynamic braking resistor overload  
16 Overheat  
B
op2  
C
op3  
D
ol1  
E
ol2  
F
olr  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
oh  
17 Emergency stop  
e
18 EEPROM fault  
eep1  
eep2  
eep3  
err2  
err3  
err4  
err5  
err6  
19 Initial read error  
20 Initial read error  
21 Inverter RAM fault  
22 Inverter ROM fault  
23 CPU fault  
24 Communication time-out error  
25 Gate array fault  
1A  
26 Output current detector error  
err7  
1B  
1D  
1E  
20  
21  
22  
24  
25  
26  
27  
28  
29  
2A  
2B  
2C  
2D  
2E  
2F  
32  
33  
34  
35  
36  
37  
27 Option error  
err8  
uc  
29 Low current operation status  
30 Undervoltage (main circuit)  
32 Over-torque trip  
up1  
ot  
33 Ground fault trip  
ef1  
34 Ground fault trip  
ef2  
36 Dynamic braking abnormal element  
37 Overcurrent during acceleration (element overheat)  
38 Overcurrent during deceleration (element overheat)  
ocr  
oc1p  
oc2p  
oc3p  
etn  
39 Overcurrent during fixed speed operation (element overheat)  
40 Tuning error  
41 Inverter type error  
etyp  
e-10  
e-11  
e-12  
e-13  
oh2  
42 Analog input terminal overvoltage  
43 Abnormal brake sequence  
44 Disconnection of encoder  
45 Speed error  
46 External thermal  
47 Step-out (for PM motors only)  
50 Terminal input error  
sout  
e-18  
e-19  
e-20  
e-21  
e-22  
e-23  
51 Abnormal CPU2 communication  
52 V/f control error  
53 CPU1 fault  
54 Abnormal logic input voltage  
55 Option 1 error  
56  
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E6581315  
38  
39  
3A  
54  
55  
56  
56 Option 2 error  
e-24  
e-25  
e-26  
etn1  
etn2  
etn3  
57 Stop position retaining error  
58 CPU2 fault  
84  tuning error  
85  tuning error  
86 Motor constant setting error  
Inverter model (capacity) code (FB05)  
Data  
Model  
Data  
(decimal number)  
(hexadecimal number)  
VFAS1-2004P  
VFAS1-2007P  
VFAS1-2015P  
VFAS1-2022P  
VFAS1-2037P  
VFAS1-2055P  
VFAS1-2075P  
VFAS1-2110P  
VFAS1-2150P  
VFAS1-2185P  
VFAS1-2200P  
VFAS1-2300P  
VFAS1-2370P  
VFAS1-2450P  
VFAS1-2550P  
VFAS1-2750P  
VFAS1-4007P  
VFAS1-4015P  
VFAS1-4022P  
VFAS1-4037P  
VFAS1-4055P  
VFAS1-4075P  
VFAS1-4110P  
VFAS1-4150P  
VFAS1-4185P  
VFAS1-4220P  
VFAS1-4300P  
VFAS1-4370P  
VFAS1-4450P  
VFAS1-4550P  
VFAS1-4750P  
VFAS1-4900P  
VFAS1-4110KP  
VFAS1-4132KP  
VFAS1-4160KP  
VFAS1-4200KP  
VFAS1-4220KP  
VFAS1-4280KP  
VFAS1-4355KP  
VFAS1-4400KP  
VFAS1-4500KP  
2
2
4
4
6
6
7
7
9
9
A
10  
11  
108  
109  
110  
111  
112  
113  
114  
115  
116  
36  
38  
39  
41  
42  
43  
44  
45  
46  
47  
48  
49  
50  
51  
52  
53  
54  
55  
56  
57  
58  
60  
62  
63  
64  
B
6C  
6D  
6E  
6F  
70  
71  
72  
73  
74  
24  
26  
27  
29  
2A  
2B  
2C  
2D  
2E  
2F  
30  
31  
32  
33  
34  
35  
36  
37  
38  
39  
3A  
3C  
3E  
3F  
40  
57  
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E6581315  
8.3.Utilizing panel (LEDs and keys) by communication  
The VF-AS1 can display data that is not related to the inverters through an external controller or  
other means. Input by key operations can also be executed. The use of inverter resources re-  
duces the cost for the entire system.  
8.3.1. LED setting by communication  
Desired LED information can be displayed by communication.  
<How to Set>  
Set the standard monitor display selection parameter to “communication LED setting  
(=).”  
When in the standard monitor mode status, LED information is displayed according to the setting of  
Communication Number FA65. (Set to Communication Number FA65 = 1 and initial data “”  
in shipment setting)  
In case of an alarm while setting communication LEDs, the alarm display will alternately display  
specified LED data and alarm message.  
For example, if an over-current alarm (alarm display “”) occurs while “.” is displayed by this  
function, “” and “.” will be displayed alternately.  
Commu-  
nication  
Number.  
FA65  
Shipment  
setting  
Parameter Name  
Range  
Select display by communication  
0: Numeric data (FA66, FA67, FA68)  
1
1: ASCII data 1 (FA70, FA71, FA72, FA73,  
FA74)  
2: ASCII data 2 (FA75, FA76, FA77, FA78,  
FA79)  
FA66  
FA67  
Numeric display data  
(Enabled if FA65=0)  
Decimal point position  
(Enabled if FA65=0)  
0-9999  
0
0
0: No decimal point (xxxx)  
1: First digit below decimal point (xxx.x)  
2: Second digit below decimal point (xx.xx)  
0:Hz off, % off, 1:Hz on, % off  
2:Hz off, % on, 3:Hz on, % on  
0 – 127 (0 – 7FH)  
FA68  
FA70  
LED data 0 for unit  
(Enabled if FA65=0)  
ASCII display data 1, first digit from  
left  
0
64H (’d’)  
41H (’A’)  
74H (’t’)  
41H (’A’)  
(See ASCII LED display code chart)  
(Enabled if FA65=1)  
ASCII display data 1, second digit  
from left  
(Enabled if FA65=1)  
ASCII display data 1, third digit from  
left  
FA71  
FA72  
FA73  
0 – 256 (0 – FFH)  
(See ASCII LED display code chart)  
0 – 256 (0 – FFH)  
(See ASCII LED display code chart)  
(Enabled if FA65=1)  
ASCII display data 1, fourth digit from 0 – 127 (0 – 7FH)  
left  
(See ASCII LED display code chart)  
(Enabled if FA65=1)  
LED data 1 for unit  
(Enabled if FA65=1)  
ASCII display data 2, first digit from  
left  
FA74  
FA75  
0:Hz off, % off, 1:Hz on, % off  
2:Hz off, % on, 3:Hz on, % on  
0 – 127 (0 – 7FH)  
0
30H (’0’)  
(See ASCII LED display code chart)  
(Enabled if FA65=2)  
ASCII display data 2, second digit  
from left  
(Enabled if FA65=2)  
ASCII display data 2, third digit from  
left  
(Enabled if FA65=2)  
ASCII display data 2, fourth digit from 0 – 127 (0 – 7FH)  
left  
FA76  
FA77  
FA78  
FA79  
0 – 256 (0 – FFH)  
(See ASCII LED display code chart)  
30H (’0’)  
30H (’0’)  
30H (’0’)  
0
0 – 256 (0 – FFH)  
(See ASCII LED display code chart))  
(See ASCII LED display code chart)  
(Enabled if FA65=2)  
LED data 2 for unit  
(Enabled if FA65=2)  
0:Hz off, % off, 1:Hz on, % off  
2:Hz off, % on, 3:Hz on, % on  
58  
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E6581315  
Block Communication Function for LED Display  
To display LED data for ASCII display that is synchronized to each digit, set data for each digit and  
validate this set data by display selection by communication (Communication Number FA65).  
Synchronization can also be achieved by batch writing LED data parameters after changing the fol-  
lowing block communication mode parameters and by sending data by block communication.  
Writing in the block communication function will be writing in the RAM only due to the EEPROM life  
for write operations. The LED data will reset to the initial value ““ when the power is turned  
off, in failure resetting or when standard shipment settings are set.  
Parameter Setting  
“Block communication mode (Communication Number FA80)”  
Setting range: 0, 1 (Initial value 0)  
0: Block communication parameters ( - ) is used  
1: LED display ASCII data is used (When writing, ASCII display data 1 [Communication Num-  
ber FA70 - FA74], when reading, LED data displayed before change)  
*To validate LED data set by using LED display block communication, set standard monitor display  
selection to “communication LED select ( = ) and display selection by communication  
to “ASCII data 1 (Communication Number FA65).  
Format  
The format is the same as that used in the usual block communication mode. (For the detail infor-  
mation, see “4.1.3 Block communication transmission format”) The block communication pa-  
rameters ( - ) will become invalid. Write data will become ASCII display data 1  
(Communication Number :FA70 - FA74) fixed. LED display data that is actually being output will be  
read during reading. The specification range for write operations is 0 to 5.  
Example  
Communication LED selection ( = ) for standard monitor display selection.  
ASCII data 1 (Communication Number:FA65 = 1) for display selection by communication.  
LED display ASCII data (Communication Number: FA80 = 1) for the block communication mode.  
Current LED display status is display of initial value “”  
PC Inverter: 2F580505003000310032003300035A・・・” display command  
Inverter PC: 2F59050000640041007400410000E7 ・・・ ” displayed before change  
59  
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E6581315  
ASCII LED display data code (00H-1FH are blank.)  
Hex Code Display Char. Hex Code  
Display  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
Char. Hex Code  
Display  
Char. Hex Code  
Display  
Char.  
00H  
01H  
02H  
03H  
04H  
05H  
06H  
07H  
08H  
09H  
0AH  
0BH  
0CH  
0DH  
0EH  
0FH  
10H  
11H  
12H  
13H  
14H  
15H  
16H  
17H  
18H  
19H  
1AH  
1BH  
1CH  
1DH  
1EH  
1FH  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
20H  
21H  
22H  
23H  
24H  
25H  
26H  
27H  
28H  
29H  
2AH  
2BH  
2CH  
2DH  
2EH  
2FH  
30H  
31HT  
32H  
33H  
34H  
35H  
36H  
37H  
38H  
39H  
3AH  
3BH  
3CH  
3DH  
3EH  
3FH  
SP  
40H  
41H  
42H  
43H  
44H  
45H  
46H  
47H  
48H  
49H  
4AH  
4BH  
4CH  
4DH  
4EH  
4FH  
50H  
51H  
52H  
53H  
54H  
55H  
56H  
57H  
58H  
59H  
5AH  
5BH  
5CH  
5DH  
5EH  
5FH  
BLANK  
@
A
B
C
D
E
F
G
H
I
60H  
61H  
62H  
63H  
64H  
65H  
66H  
67H  
68H  
69H  
6AH  
6BH  
6CH  
6DH  
6EH  
6FH  
70H  
71H  
72H  
73H  
74H  
75H  
76H  
77H  
78H  
79H  
7AH  
7BH  
7CH  
7DH  
7EH  
7FH  
BLANK  
`
a
b
c
d
e
f
!
#
$
%
&
g
h
i
(
)
BLANK  
BLANK  
DGP  
*
J
j
+
,
K
L
k
l
-
M
N
O
P
Q
R
S
T
U
V
W
X
Y
Z
[
m
n
o
p
q
r
DGP  
.
/
0
1
2
3
4
5
6
7
8
9
:
s
t
u
v
w
x
y
z
{
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
BLANK  
;
<
=
>
?
]
|
}
BLANK  
BLANK  
^
BLANK  
BLANK  
Æ
BLANK  
_
*Dots to show decimal points and other uses can be added by setting (80H) Bit 7 (highest bit).  
Example: “0.” to display “60.0” can be added by “30H + 80H = B0H.”  
60  
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E6581315  
8.3.2.Key utilization by communication  
The VF-AS1 can use the panel keys on the inverters through external communication.  
Key Monitoring Procedure  
Set panel key selection (Communication Number: FA10) to “1” to set the external key mode. How-  
ever, if communication duration is less than 1sec to avoid an inverter operation shutdown in com-  
munication disruption, communication must always be maintained, such as monitoring key data and  
LED data to automatically reset inverter operations to inverter key operation (FA10 = 0). Set to the  
external communication key mode (FA10 = 1) to disable the key function of the inverters so that in-  
verter operation will not be affected by pressing of the keys on the inverters. By monitoring key in-  
formation, which is input by the keys on the inverters in this condition, through inverter key data  
(Communication Number; FC01), the keys on the inverters can be operated through a controller and  
other devices.  
* When the key mode is the external key mode, key operation as an inverter function is disabled and  
the inverters cannot be stopped by pressing the STOP key to stop inverter operation. Enable  
emergency stop through an external terminal or other device when an inverter stop is desired.  
Panel Key Selection (Communication Number:FA10)  
The panel key selection parameter (Communication Number; FA10) discriminates which keys are to be used, panel keys  
on the inverters or keys sent by external communication, as panel keys used in panel processing of the inverters.  
Communication No.FC01  
Panel key data of inverters  
FA10=”0”  
Communication No.FC00  
Key data for inverter  
control panel processing  
Communication No.FA11  
FA10=”1”  
External communication  
key data  
Keys on inverters enabled (Communication Number; FA10 = 0):  
Key data: Data of keys on inverters (Communication Number : FC01)  
Bit7  
Bit6  
Bit5  
Bit4  
Bit3  
Bit2  
Bit1  
Bit0  
EASY  
KPP  
ENT  
MODE  
DOWN  
UP  
STOP  
RUN  
“KPP” for Bit 7 indicates that panel keys are mounted on the inverters.  
External keys enabled (Communication Number; FA10 = 1):  
Key data: External key data (Communication Number: FA11)  
Bit7  
Bit6  
Bit5  
Bit4  
Bit3  
Bit2  
Bit1  
Bit0  
-
EASY  
ENT  
MODE  
DOWN  
UP  
STOP  
RUN  
Key monitoring (Communication Number : FC00):  
Information of the enabled keys on the inverters can be monitored.  
Bit7  
Bit6  
Bit5  
Bit4  
Bit3  
Bit2  
Bit1  
Bit0  
KPP  
EASY  
ENT  
MODE  
DOWN  
UP  
STOP  
RUN  
“KPP” for Bit 7 indicates that panel keys are enabled on the inverters.  
61  
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E6581315  
9.Parameter data  
Explanation of parameters for VF-AS1 series is described here. For communication purposes, see  
the parameter list on inverter's instruction manual regarding the communication number, adjustment  
range and so forth.  
Referring to the parameter list  
 <Example of excerpts from the inverter’s instruction manual>  
Minimum set-  
ting unit  
Refer-  
ence  
Communi-  
Default  
setting  
Write during  
running  
Title  
Function  
Adjustment range  
(Panel/Communi  
cation)  
cation No.  
auh  
au1  
-
History function  
1/1  
1/1  
-
-
5.1  
5.2  
0000  
Automatic accelera- 0:Deselect  
0
Disabled  
tion/deceleration  
1:Automatic setting  
2:Automatic setting (during  
acceleration only)  
0:Deselect  
1:Automatic torque boost +  
auto-tuning 1  
au2  
acc  
0001  
Automatic torque  
boost  
1/1  
-
Disabled  
Enabled  
5.3  
5.2  
Acceleration time  
1
0.1~6000 sec.  
0.1/0.1 *2  
*1  
0009  
0007  
0: -  
1:50 Hz default setting  
2:60 Hz default setting  
3:Factory default setting  
10:Acceleration/deceleration  
time setting 0.01  
sec.~600.0 sec.  
Factory default  
setting  
typ  
1/1  
5.20  
-
Disabled  
11:Acceleration/deceleration  
time setting 0.1  
sec.~6000sec.  
                       :  
 *1: Default values vary depending on the capacity.  
 *2: Changing the parameter  enables to set to 0.01 sec. (adjustment range: 0.01~600.0 sec.).  
- The summary of parameter list relating to the communication is as follows.  
(1) “Title” means the display on the inverter panel.  
(2) “Communication number” is affixed to each parameter that is necessary for designating the parameter for com-  
munication.  
(3) "Adjustment range" means a data range adjustable for a parameter, and the data cannot be written outside the  
range. The data have been expressed in the decimal notation. For writing the data through the communication  
function, take the minimum setting unit into consideration, and use hexadecimal system.  
(4) "Minimum setup unit" is the unit of a single data (when the minimum unit is "-", 1 is equal to 1).  
For example, the "minimum setup unit" of acceleration time () is 0.01, and 1 is equal to 0.01s. For setting a  
data to 10 seconds, transmit 03E8h [10÷0.01=1000d=03E8h] by communication.  
(5) If FA09 is set to 0, the acceleration/deceleration time parameters acc, dec, f500, f501, f510,  
f511, f514, and f515can be set in units of 0.01 sec.  
Q Acceleration/deceleration setting time unit (FA09)  
Communication No.  
FA09  
Function name  
Unit  
Adjustment range  
0: 0.01 sec. (0.01-600.0)  
1: 0.1 sec. (0.1-6000.0)  
Acceleration/deceleration time unit  
62  
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Command parameters  
For those parameters that contain data only in the RAM and not in the EEPROM, their data return to  
initial values when the power is turned off, in failure resetting, or when standard shipment settings  
are set. Note that parameters without data storage in the EEPROMs will be written in the RAM only  
even if the command W (writing in EEPROMs and RAM) is executed.  
Q Commands                          NOTE : Data is expressed in decimal notation.  
Communica-  
Min.  
Setting  
Unit  
Write  
During  
Operation  
tion  
Num-  
ber.(HEX)  
Adjustment Range  
Initial  
Value  
EEP  
ROM  
Function  
1
Command 1 (2-wire RS485)*  
FA00  
0 to 65535  
0
0
yes None  
FA01 Frequency command value (2- 0 to Max. frequency 0.01Hz  
yes None  
1
wire RS485)*  
()  
FA03 Operation panel operation  
Low-limit frequency 0.01Hz  
() to High-limit  
0
yes Available  
frequency *2  
frequency ()  
0 to 65535  
1
Command 1 (4-wire RS485)*  
FA04  
0
0
yes None  
yes None  
FA05 Frequency command value (4- 0 to Max. frequency 0.01Hz  
1
wire RS485)*  
()  
4
Panel key selection*  
FA10  
0: Main unit  
1: Comunication  
0 to 65535  
0
0
yes None  
yes None  
FA11 External communication key  
4
data*  
1
1
FA20  
FA22  
0 to 65535  
0 to 65535  
0
0
0
yes None  
yes None  
yes None  
Command 2 (2-wire RS485)  
Command 2 (4-wire RS485)  
FA30 Torque command value (2-wire -250.00 to 250.00  
RS485)  
0.01%  
FA32 Torque command value (4-wire -250.00 to 250.00  
0.01%  
0
yes None  
RS485)  
3
Terminal output data*  
FM analog output data*  
FA50  
FA51  
0 to 255  
1
1
0
0
yes None  
yes None  
3
3
0 to 2047  
(11-bit resolution)  
0 to 2047  
(11-bit resolution)  
0 to 2047  
(11-bit resolution)  
0 to 2047  
(11-bit resolution)  
AM analog output data*  
MON1 analog output data*  
MON2 analog output data*  
FA52  
FA53  
FA54  
1
1
0
0
0
1
yes None  
yes None  
yes None  
yes Available  
3
3
1
FA65 Select display by communica- 0 to 2  
4
tion*  
4
Numerical display data*  
FA66  
FA67  
FA68  
0-9999  
0 to 2  
1
0
0
0
yes Available  
yes Available  
yes Available  
yes Available  
4
Decimal point position*  
4
LED data for unit 0*  
0 to 3  
FA70 ASCII display data 1  
0 to 127  
100  
(‘d’)  
4
First digit from left*  
FA71 ASCII display data 1  
Second digit from left*  
0 to 255  
0 to 255  
0 to 127  
65  
(‘A’)  
yes Available  
yes Available  
yes Available  
4
FA72 ASCII display data 1  
116  
(‘t’)  
4
Third digit from left*  
FA73 ASCII display data 1  
65  
(‘A’)  
4
Fourth digit from left*  
4
LED data for unit1*  
FA74  
0 to 3  
0
yes Available  
yes Available  
FA75 ASCII display data 2  
0 to 127  
48  
(‘0’)  
4
First digit from left*  
FA76 ASCII display data 2  
Second digit from left*  
0 to 255  
0 to 255  
0 to 127  
48  
(‘0’)  
yes Available  
yes Available  
yes Available  
4
FA77 ASCII display data 2  
48  
(‘0’)  
4
Third digit from left*  
FA78 ASCII display data 2  
48  
(‘0’)  
4
Fourth digit from left*  
4
LED data for unit 2*  
FA79  
0 to 3  
0 to 1  
0
0
yes Available  
yes Available  
4
Block communication mode*  
FA80  
63  
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E6581315  
1: Enable the communication command or communication frequency setting before setting these  
parameters are set. Otherwise, the parameters will not function. See “8.1 Command by  
communication” for the method to enable them.  
2: Note that the Communication Number for operation panel operation frequency is FA02 in the  
VF-S7 and VF-S9 series.  
3: See “8.1 Communication commands (commande from the computer)” for the detail information.  
4: See “8.3 Utilizing panel (LEDs and keys) by communication” for the detail information.  
64  
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Monitor parameters  
*These Parameters are read-only (monitor-only) parameters.  
Communication No.  
Function  
Unit  
Remarks  
Current  
value  
Trip data held  
FC00  
Monitor of key data (Effective  
data)  
Refer to Section  
8.3.  
FC01  
FC90  
FC91  
FD00  
FD01  
FD02  
FD03  
FD04  
FD05  
FD06  
FD07  
Monitor of inverter keypad data  
Trip code  
Alarm code  
Refer to Section  
8.2.  
FE00  
FE01  
FE02  
FE03  
FE04  
FE05  
FE06  
FE07  
FE08  
FE10  
FE11  
FE12  
FE13  
FE14  
FE15  
FE16  
FE17  
FE18  
FE19  
FE20  
FE21  
FE22  
FE23  
FE24  
Output frequency  
Inverter status 1  
0.01Hz  
Frequency command value  
Output current  
0.01Hz  
0.01%  
0.01%  
0.01%  
Input voltage (DC detection)  
Output voltage  
Input terminal information  
Output terminal information  
CPU version 1 (application)  
Past trip 1 (latest)  
Past trip 2  
Refer to Section  
8.2.  
Refer to Section  
8.2.  
Past trip 3  
Past trip 4 (earliest)  
Cumulative operation time  
Compensated frequency  
Speed feedback (real time)  
Speed feedback (1-sec. filter)  
Torque  
1h  
FD15  
FD16  
FD17  
FD18  
FD19  
FD20  
FD21  
FD22  
FD23  
FD24  
0.01Hz  
0.01Hz  
0.01Hz  
0.01%  
0.01%  
0.01%  
0.01%  
0.01Hz  
0.01%  
Torque command  
Torque current  
Exciting current  
PID feedback value  
Motor overload factor (OL2 data)  
Inverter overload factor (OL1  
data)  
0.01%  
1%  
FD25  
FE25  
Regenerative braking resistance  
overload factor (OLr data)  
Motor load factor  
FD26  
FD27  
FD28  
FE26  
FE27  
FE28  
1%  
1%  
Inverter load factor  
Regenerative braking resistance  
load factor  
1%  
FD29  
FD30  
FE29  
FE30  
FE35  
FE36  
FE37  
FE38  
FE39  
FE42  
Input power  
0.01kW  
0.01kW  
0.01%  
0.01%  
0.01%  
0.01%  
0.01%  
Output power  
RR/S4 input  
VI/II input  
Refer to Section  
8.2.  
RX input  
Option AI1  
Option AI2  
FD42  
Inverter status 2  
Refer to Section  
8.2.  
FE43  
FE44  
FE45  
FE46  
FE48  
FE49  
MON1 output (analog option 1)  
MON2 output (analog option 2)  
Command mode status  
Frequency setting mode status  
PID command  
FD45  
FD46  
FD48  
FD49  
Refer to Section  
8.2.  
0.01Hz  
Inverter status 3  
Refer to Section  
8.2.  
65  
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E6581315  
FD50  
FD51  
Light-load high-speed torque 1  
Light-load high-speed torque 2  
MY monitor 1  
0.01%  
0.01%  
FE60  
FE61  
FE62  
FE63  
FE70  
FE71  
FE73  
FE76  
FE77  
FE79  
MY monitor 2  
MY monitor 3  
MY monitor 4  
Rated current  
0.1a  
0.1V  
Rated voltage  
CPU version 2 (motor)  
Integral input power  
Integral output power  
Part replacement alarm informa-  
tion  
0.01kWh  
0.01kWh  
Refer to Section  
8.2.  
FE80  
FE84  
Cumulative power ON time  
Binary input value (option)  
1h  
FD84  
66  
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Appendix 1 Table of data codes  
JIS (ASCII) codes  
Higher orde  
0
1
2
3
4
5
6
7
Lower order  
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
F
NUL  
TC7(DLE)  
DC1  
(SP)  
!
_
TC1(SOH)  
TC2(STX)  
TC3(ETX)  
TC4(EOT)  
TC5(ENQ)  
TC6(ACK)  
BEL  
DC2  
DC3  
DC4  
TC8(NAK)  
TC9(SYN)  
TC10(ETB)  
CAN  
FE0(BS)  
FE1(HT)  
FE2(LF)  
FE3(VT)  
FE4(FF)  
FE5(CR)  
SO  
EM  
SUB  
ESC  
IS4(FS)  
IS3(GS)  
IS2(RS)  
IS1(US)  
SI  
DEL  
CR: Carriage return  
Ex.: Code 41 = Character A  
67  
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Appendix 2 Response time  
The communication response time can be calculated from data communication time and inverter  
processing time. When wishing to know the communication response time, calculate using the  
following as a reference  
Interval corresponding to 3.5 bytes  
Data processing time of inverter (Approx. 8 ms)  
Data transmission time  
Data transmission time  
PC Inverter  
Inverter PC  
Response time  
Data transmission time  
1
Data transmission time =  
×number of bytes transmitted×number of bits  
baudrate  
* Number of bits = start bit + data frame length + parity bit + stop bit  
* Minimum number of bits = 1 + 8 + 0 + 1 = 10 bits  
* Maximum number of bits = 1 + 8 + 1 + 2 = 12 bits  
<An example of the calculation of the transmission time: 19200 bps, 8 bytes, 11 bits>  
1
Data transmission time =  
×8×11= 4.6ms  
19200  
Data processing time of inverter  
Data processing time: maximum 8 ms  
68  
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Appendix 3 Compatibility with the communication function  
of the VF-A7  
To provide consistency in communication procedures, the communication function of the VF-AS1  
series of inverters has been designed based on the protocols used for the Toshiba VF-A7 series of  
inverters. With regard to compatibility, however, VF-A7 users should check the items described be-  
low before using the communication function of their inverters.  
To VF-AS1 inverter users:  
Some parameters of the VF-A7 are different from those of the VF-AS1 in function or adjustment  
range (upper and lower limits), even though they have the same title or the same communication  
number. So, when accessing a parameter, consult the VF- A7 inverter’s instruction manual to see if  
the parameter is identical to the corresponding parameter of the VF-AS1. If the parameter differs,  
modify the computer program to suit your inverter. To avoid hazards, never copy parameters from  
one model of inverter to another.  
Comparison of communication-related items  
The table below gives a comparison of communication-related items to be kept in mind when re-  
placing VF-A7 inverters with VF-AS1 inverters or when connecting VF-A7 inverters and VF-AS1 in-  
verters to the same network. It does not cover any items common to the VF-A7 and VF-AS1 series  
of inverters.  
Model  
VF-A7 series  
VF-AS1 series  
Reference  
Refer to  
Item  
32-bit mode  
For some parameters, including accel-  
eration/deceleration time parameters,  
data communication are carried out in  
32-bit mode.  
32-bit mode is not available. For all  
parameters, access is made in 16-bit Section 9.  
mode.  
Handling of negative  
data specified with pa-  
rameters  
Access is made in 32-bit mode.  
Access is made in 16-bit mode. To  
see if the value specified with a  
parameter is signed or not, check the  
adjustment range of the parameter.  
No frame can be divided into smaller  
frames. Do not place an interval cor-  
responding to less than 1.5 bytes of  
data between frames to be sent.  
0.1 sec.  
Division of a frame  
A frame can be sent with it divided into  
smaller frames if all the frames can be  
sent within approx. 0.5 sec.  
Refer to  
Section  
3.1.  
Communication time-  
out period (guide)  
0.5 sec.  
Receipt information in  
front of the start code  
Even if there is receipt information in  
front of the start code of a frame re-  
ceived, the frame is assumed to begin  
with the start code.  
A frame must always begin with a start  
code, otherwise it will be rejected.  
Reset command  
RS485 baud rate  
When an inverter receives a reset com- When an inverter receives a reset  
mand, it sends back a response before it command, it sends back no response.  
is reset.  
Refer to  
Section  
8.1.  
Refer to  
Section  
7.1.  
1200 to 38400 bps  
9600 to 38400 bps  
Notice  
Do not use communication programs written for another series of inverters.  
Even though parameters have the same title and the same communication number, they may be different  
in function. When using a parameter, always check its specifications in the instruction manual for your  
inverter. If the specifications of the parameter differ, modify the computer program to suit your inverter.  
To avoid hazards, do not copy parameters from one model of inverter to another.  
Even though parameters have the same titles and communication numbers, they may be different in  
function.  
69  
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Appendix 4 Troubleshooting  
If a problem arises, diagnose it in accordance with the following table before making a service call. If  
the problem cannot be solved by any remedy described in the table or if no remedy to the problem is  
specified in the table, contact your Toshiba dealer.  
Problem  
Remedies  
Reference  
Communication will not take - Are both the computer and the inverter turned on?  
place.  
- Are all cables connected correctly and securely?  
- Are the same baud rate, parity and bit length set for every unit on the  
network?  
Chapter 7  
Section 4.1  
Section 5.1  
Chapter 9  
Inverter  
instruction  
manual  
An error code is returned.  
- Is the data transmission format correct?  
- Does the data written fall within the specified range?  
- Some parameters cannot be written during inverter operation.  
Changing should be attempted when the inverter is in halt.  
The trip err5 and alarm t - Check the cable connection and the timer setting.  
Section 7.3  
occur.  
Frequency instructions from the - Is the frequency setting mode selection parameter set to “computer”? Section 8.1  
computer have no effect.  
Commands, including the run and - Is the command mode selection parameter set to “computer”?  
Section 8.1  
stop commands, from the com-  
muter have no effect.  
- Isthe inverter connected correctly?  
- Are you sure the receive line and the send line are not in contact with  
each other?  
During RS485 communication,  
an inverter sends back respons-  
es repeatedly an infinite number  
of times.  
Refer  
Appendix  
2.  
to  
A change to a parameter does Some communication-related parameters do not take effect until the  
Chapter 7  
not take effect.  
inverter is reset. To make them take effect, turn the inverter off tempo-  
rarily, then turn it back on.  
The setting of a parameter was When using the TOSHIBA Inverter Protocol, use the W command to Section 4.2  
changed, but it returns to its write data into the EEPROM. If you use the P command that writes data  
original setting when the inverter into the RAM only, the data will be cleared when the inverters are reset.  
is turned off.  
70  
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Appendix 5 Connecting for RS485 communication  
Connector diagram for 2-wire RS485 communication  
                    
Pin-8  
Pin-1  
           
Signal name  
RXD+/TXD+  
RXD-/TXD-  
FWE  
Pin number  
Description  
4
5
Same phase reception data (positive line)  
Anti-phase reception data (negative line)  
FEW (Do not connect the cable.)  
Ground line of signal data  
6
SG  
8
(3)  
2
PRG(TX)  
PRG(RX)  
P11  
PRG (Do not connect the cable.)  
PRG (Do not connect the cable.)  
11V (Do not connect the cable.)  
1
7
Connecting diagram for 2-wire RS485 communication  
* Never use pin-7 (P11).  
Straight  
Straight  
Straight  
Slave  
Slave  
Master  
Slave  
CN1  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
RXD+/TXD+  
RXD-/TXD-  
Pin-4  
Pin-5  
SG  
SG  
Pin-8  
(Pin-3)  
SG  
SG  
Terminating resistance  
120Ω-1/2W  
71  
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Connector diagram for 4-wire RS485 communication  
                    
Pin-8  
Pin-1  
Signal name  
RXA  
Pin number  
4
Description  
Same phase reception data (positive line)  
           
RXB  
TXA  
TXB  
SG  
5
3
Anti-phase reception data (negative line)  
Same phase transmitting data (positive line)  
Anti-phase transmitting data (negative line)  
Ground line of signal data  
6
8
(2)  
1
Open (Do not connect the cable.)  
11V (Do not connect the cable.)  
P11  
7
*This table shows signal line of inverter side. (Example: RXA signal is received by  
inverter.)  
Connecting diagram for 4-wire RS485 communication  
Straight  
Cross  
Straight  
Slave  
Master  
Slave  
Slave  
CN1  
Pin-4  
RXA  
RXB  
TXA  
TXB  
SG  
RXA  
RXB  
TXA  
TXB  
SG  
RXA  
RXB  
TXA  
TXB  
SG  
RXA  
RXB  
TXA  
TXB  
SG  
Pin-5  
Pin-3  
Pin-6  
Pin-8  
(
Pin-2)  
Terminating resistance  
120Ω-1/2W  
* When using 2-wire type, short RXB to TXB and RXA to TXA.  
* Never use pin-1 (Open) and pin-7 (P11).  
72  
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