Instruction List - Type
- CIMON (Unlicensed)
Contact
Instruction | Type of Input | Note |
LD | LD (S) | Takes ON/OFF Data For a Contact Of One Circuit AS Operation Result. |
LDI | LDI (S) | Takes ON/OFF Data For b Contact Of One Circuit As Operation Result. |
LDP | LDP (S) | If Input Condition Is ON From OFF, Sets For One Scan. |
LDF | LDF (S) | If Input Condition Is OFF From ON, Sets For One Scan. |
AND | AND (S) | AND-Operates Contact a Of The Assigned Contact And Connected Contants In Series, And Takes The Result As Operation Result. |
ANDI | ANDI (S) | AND-Operates Contact b Of The assigned Contact And The Connected Contact In Series, Takes The Result As Operation Result. |
ANDF | ANDF (S) | If Input Condition To Contact To Detect Connection In Series Is Off From On, Device S Is Set For One Scan. |
ANDP | ANDP (S) | If Input Condition To Contact To Detect Connection In Series Is On From Off, Device S Is Set For One Scan. |
OR | OR (S) | OR-Operates a Contact Of The Assigned Contact And The Connected Contact In Parallel And Takes The Result As Operation Result. |
ORI | ORI (S) | OR-Operates b Contact Of the Assigned Contact And The Connected Contact In Parallel, And Takes The Result As Operation Result. |
ORP | ORP (S) | If Input Condition Of Connection In Parallel Contact Is OFF From ON, Sets For One Scan. |
ORF | ORF (S) | If Input Condition Of Connection In Parallel Contact Is OFF From ON, Sets For One Scan. |
INV | INV | Inverts The Left Circuit, A Contact Circuit To B Contact Circuit And B Contact Circuit To A Contact Circuit. |
Connection
Instruction | Type of Input | Note |
ANB | ANB | AND-Operates Blocks And Takes The Result As Operation Result. |
ORB | ORB | OR-Operates Blocks And Takes The result As Operation Result. |
MPS | MPS | It IS Used To Branch At First. Stores Operation Result In Memory. |
MRD | MRD | It Is Used To Relay Branching. Reads The Stored State From Memory And Operates The Result. |
MPP | MPP | It Is Used to End Branching. Reads The Stored State From Memory And Operates The Result. |
Output
Instruction | Type of Input | Note |
OUT | OUT (D) | Outputs Operation Result To The Assigned Contact. |
SET | SET (D) | If Input Condition Is ON, Keeps Output Contact In ON State. Though The Input Is OFF, Keeps Setting Output. |
PLS | PLS (D) | If INput Condition IS ON From OFF, Sets The Assigned Contact For One Scan. Otherwise, Resets. |
PLF | PLF (D) | If Input Condition Is OFF From ON, Sets The Assigned Contact For One Scan. Otherwise, Resets. |
Master Control
Instruction | Type of Input | Note |
MC | MC (n) | If Input Of MC Is ON, Operates Up To Same MCR. If Input Conditon Is OFF, Does Not Operates. |
MCR | MCR (n) | If Input Of MC Is ON, Operates Up To Same MCR. If Input Conditon Is OFF, Does Not Operates. |
Jump
Instruction | Type of Input | Note |
JME | JME (n) | If Input Of JMP n Instruction Is On, Jumps Next To JME n And Does Not Process All The Instructions Up To JME n. |
JMP | JMP (n) | If Input Of JMP n Instruction Is On, Jumps Next To JME n And Does Not Process All The Instructions Up To JME n. |
JMPP | JMPP (n) | If JMPP n Instruction Input Is On, Jumps Next To JME n And Does Not Process All The Instructions Up To JME n. |
Call
Instruction | Type of Input | Note |
CALL | CALL (n) | If Input Condition Is ON While Processing Program, Processes The Program Between The SBRT n To The RET According To The CALL n. |
CALLP | CALLP (n) | If Input Condition Is ON While Processing Program, Processes The Program Between The SBRT n To The RET According To The CALL n. |
ECALL | ECALL (Progam ID) (n) | Calls Sub-Routine From Other Program File. (Pn-Point Number Of Sub-Routine) |
ECALLP | ECALLP (Program ID) (n) | Calls Sub-Routine From Other Program File. (Pn-Point Number Of Sub-Routine) |
SBRT | SBRT (n) | If Input Condition Is ON While Running Program, Runs The Program Between SBRT n And RET Accoding To CALL n. |
RET | RET | If Input Condition Is ON While Running Program, Runs The Program Between SBRT n And RET Accoding To CALL n. |
Interrupt
Instruction | Type of Input | Note |
EI | EI (n) | Operates Time Driven Interrrupt Assigned To n. |
DI | DI (n) | Stops Operating Time Driven Interrupt Assigned To n. |
GEI | GEI | Operates Time Driven Interrrupt In Entire Program. |
GDI | GDI | Stops Operating Time Driven Interrrupt In Entire Program. |
IRET | IRET | Shows THe End OF Interrupt Program. |
Loop
Instruction | Type of Input | Note |
FOR | FOR (n) | Runs The Step Next To NEXT Instruction After Has Processed Between FOR And NEXT At n Times. |
NEXT | NEXT | Runs The Step Next To NEXT Instruction After Has Processed Between FOR And NEXT At n Times. |
BREAK | BREAK | Comes Out From The FOR ~ NEXT Instruction. |
BREAKP | BREAKP | Comes Out From The FOR ~ NEXT Instruction. |
END
Instruction | Type of Input | Note |
END | END | It Is The Instruction To Inform Ending Main Routine Program. In Case Jump Instruction Prior To It Is Operated, It Is Not Operated. |
CEND | CEND | If input condition is turned on, ends main routine program. |
CENDP | CENDP | If input condition is turned on, ends main routine program. |
PEND | PEND | It Means End Of Program And Is Put On The Last Part. |
STOP | STOP | To Stop Operation At The Time When Users Want, Converts To Program Mode After Finishing The Scan In Progress. |
INITEND | INITEND | Ends Initialization Program ANd Runs Scan Program. |
Compare
Instruction | Type of Input | Note |
LD< | LD< (S1) (S2) | If Data In S1 Is Less Than Data In S2, Sets Result Of The Current Operation. |
LD<= | LD<= (S1) (S2) | If Data In S1 Is Less Than Or Equal To Data In S2, Sets Result Of The Current Operation. |
LD<> | LD<> (S1) (S2) | If Data In S1 Is Not Equal To Data In S2, Sets Result Of The Current Operation. |
LD= | LD= (S1) (S2) | If Data In S1 Is Equal To Data In S2, Sets Result Of The Current Operation. |
LD> | LD> (S1) (S2) | If Data In S1 Is Greater Than Data In S2, Sets Result Of The Current Operation. |
LD>= | LD>= (S1) (S2) | If Data In S1 Is Greater Than Or Equal To Data In S2, Sets Result Of The Current Operation. |
AND< | AND< (S1) (S2) | If Data S1 Is Less Than Data S2, ON. If Greater Than Or Equal To, OFF. AND-Operates The Result And Result Of The Current Operation. |
AND<= | AND<= (S1) (S2) | If Data S1 Is Less Than Or Equal To Data S2, ON. If Greater Than, OFF. AND-Operates The Result And Result Of The Current Operation. |
AND<> | AND<> (S1) (S2) | If Data S1 And Data S2 Are Not Equal, ON. If Equal, OFF. AND-Operates The Result And Result Of The Current Operation. |
AND= | AND= (S1) (S2) | If Data S1 And Data S2 Are Equal, ON. If TNot Equal, OFF. AND-Operates The Result And Result Of The Current Operation. |
AND> | AND> (S1) (S2) | If Data S1 Is Greater Than Data S2, ON. If Less Than Or Equal To, OFF. AND-Operates The Result And Result Of The Current Operation. |
AND>= | AND>= (S1) (S2) | If Data S1 Is Greater Than Or Equal To Data S2, ON. If Less Than, OFF. AND-Operates The Result And Result Of The Current Operation. |
OR< | OR< (S1) (S2) | If Data In S1 Is Less Than Data In S2, Sets.If Greater Than Or Equal To, Resets. OR-Operates The Result And Result Of The Current Operation. |
OR<= | OR<= (S1) (S2) | If Data In S1 Is Less Than Or Equal To Data In S2, Sets. If Greater Than, Resets. OR-Operates The Result And Result Of The Current Operation. |
OR<> | OR<> (S1) (S2) | If Data In S1 Is Not Equal To Data In S2, Sets. If Equal To, Off. OR-Operates The Result And Result Of The Current Operation. |
OR= | OR= (S1) (S2) | If Data In S1 Is Equal To Data In S2, Sets. If Not Equal To, Resets. OR-Operates The Result And Result Of The Current Operation. |
OR> | OR> (S1) (S2) | If Data In S1 Is Greater than Data In S2, Sets. If Less than Or Equal To, Resets. OR-Operates The Result And Result Of The Current Operation. |
OR>= | OR>= (S1) (S2) | If Data InS1 Is Greater Than Or Equal To Data In S2, Sets. If Less Than, Resets. OR-Operates The Result And Result Of The Current Operation. |
UCMP | UCMP (S1) (S2) |
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Compare (DWORD)
Instruction | Type of Input | Note |
LDD< | LDD< (S1) (S2) | If Data In S1 Is Less Than Data In S2, Sets Result Of The Current Operation. |
LDD<= | LDD<= (S1) (S2) | If Data In S1 Is Less Than Or Equal To Data In S2, Sets Result Of The Current Operation. |
LDD<> | LDD<> (S1) (S2) | If Data In S1 Is Not Equal To Data In S2, Sets Result Of The Current Operation. |
LDD= | LDD= (S1) (S2) | If Data In S1 Is Equal To Data In S2, Sets Result Of The Current Operation. |
LDD> | LDD> (S1) (S2) | If Data In S1 Is Greater Than Data In S2, Sets Result Of The Current Operation. |
LDD>= | LDD>= (S1) (S2) | If Data In S1 Is Greater Than Or Equal To Data In S2, Sets Result Of The Current Operation. |
ANDD< | ANDD< (S1) (S2) | If Double-Word Data S1 Is Less Than Double-Word Data S2, ON. If Greater Than Or Equal To, OFF. AND-Operates The Result And Result Of The Current Operation. |
ANDD<= | ANDD<= (S1) (S2) | ANDD<= (S1) (S2)" , "If Double-Word Data S1 Is Less Than Or Equal To Double-Word Data S2, On. If Greater Than, OFF. AND-Operates The Result And Result Of The Current Operation. |
ANDD<> | ANDD<> (S1) (S2) | ANDD<> (S1) (S2)" , "If Double-Word Data S1 Is Not Equal To Double-Word Data S2, ON. If Equal To, OFF. AND-Operates The Result And Result Of The Current Operation. |
ANDD= | ANDD= (S1) (S2) | ANDD= (S1) (S2)" , "If Double-Word Data S1 Is Equal To Double- Word Data S2, ON. If Not Equal to, OFF.AND-Operates The Result And Result Of The Current Operation. |
ANDD> | ANDD> (S1) (S2) | ANDD> (S1) (S2)" , "If Double-Word Data S1 Is Greater Than Double-Word Data S2, ON. If Less Than, OFF. AND-Operates The Result And Result Of The Current Operation. |
ANDD>= | ANDD>= (S1) (S2) | ANDD>= (S1) (S2)" , "If Double-Word Data S1 Is Greater Than Or Equal To Double-Word Data S2, ON. If Less Than, OFF. AND-Operates The Result And Result Of The Current Operation. |
ORD< | ORD< (S1) (S2) | If Data In S1 Is Less Than Data In S2, Sets. If Greater Than Or Equal To, Off. OR-Operates The Result And Result Of The Current Operation. |
ORD<= | ORD<= (S1) (S2) | If Data In S1 Is Less Than Or Equal To Data In S2, Sets. If Greater Than, Resets. OR-Operates The Result And Result Of The Current Operation. |
ORD<> | ORD<> (S1) (S2) | If Data In S1 Is Not Equal To Data In S2, Sets. If Equal To, resets. OR-Operates The Result And Result Of The Current Operation. |
ORD= | ORD= (S1) (S2) | If Data In S1 Is Equal To Data In S2, Sets. If Not Equal To, Resets. OR-Operates The Result And Result Of The Current Operation. |
ORD> | ORD> (S1) (S2) | If Data In S1 Is Greater Than Data In S2, Sets. If Less Than Or Equal To, Resets. OR-Operates The Result And Result Of The Current Operation. |
ORD>= | ORD>= (S1) (S2) | If Data In S1 Is Greater Than Or Equal To Data In S2, Sets. If Less Than, Resets. OR-Operates The Result And Result Of The Current Operation. |
Compare (Block)
Instruction | Type of Input | Note |
BK= | BK= (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK=P | BK=P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK<> | BK<> (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK<>P | BK<>P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK< | BK< (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK<P | BK<P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK<= | BK<= (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK<=P | BK<=P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK> | BK> (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK>P | BK>P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK>= | BK>= (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
BK>=P | BK>=P (S1) (S2) (D) (B) (n) | Compare [n] of 16 bit data from the device designated by [S1] with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. Compare 16 bit data with [n] of 16 bit data from the device designated by [S2] and stores the results from bit [n] of the device designated by [D]. |
Compare (Floating decimal point)
Instruction | Type of Input | Note |
LDE< | LDD< (S1) (S2) | If Float Data In S1 Is Less Than Float Data In S2, Sets Result Of The Current Operation. |
LDE<= | LDD<= (S1) (S2) | If Float Data In S1 Is Less Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
LDE<> | LDD<> (S1) (S2) | If Float Data In S1 Is Not Equal To Float Data In S2, Sets Result Of The Current Operation. |
LDE= | LDD= (S1) (S2) | If Float Data In S1 Is Equal To Float Data In S2, Sets Result Of The Current Operation. |
LDE> | LDD> (S1) (S2) | If Float Data In S1 Is Greater Than Float Data In S2, Sets Result Of The Current Operation. |
LDE>= | LDD>= (S1) (S2) | If Float Data In S1 Is Greater Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
ANDE< | ANDD< (S1) (S2) | If Float Data In S1 Is Less Than Float Data In S2, Sets Result Of The Current Operation. |
ANDE<= | ANDD<= (S1) (S2) | If Float Data In S1 Is Less Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
ANDE<> | ANDD<> (S1) (S2) | If Float Data In S1 Is Not Equal To Float Data In S2, Sets Result Of The Current Operation. |
ANDE= | ANDD= (S1) (S2) | If Float Data In S1 Is Equal To Float Data In S2, Sets Result Of The Current Operation. |
ANDE> | ANDD> (S1) (S2) | If Float Data In S1 Is Greater Than Float Data In S2, Sets Result Of The Current Operation. |
ANDE>= | ANDD>= (S1) (S2) | If Float Data In S1 Is Greater Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
ORE< | ORD< (S1) (S2) | If Float Data In S1 Is Less Than Float Data In S2, Sets Result Of The Current Operation. |
ORE<= | ORD<= (S1) (S2) | f Float Data In S1 Is Less Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
ORE<> | ORD<> (S1) (S2) | If Float Data In S1 Is Not Equal To Float Data In S2, Sets Result Of The Current Operation. |
ORE= | ORD= (S1) (S2) | If Float Data In S1 Is Equal To Float Data In S2, Sets Result Of The Current Operation. |
ORE> | ORD> (S1) (S2) | If Float Data In S1 Is Greater Than Float Data In S2, Sets Result Of The Current Operation. |
ORE>= | ORD>= (S1) (S2) | If Float Data In S1 Is Greater Than Or Equal To Float Data In S2, Sets Result Of The Current Operation. |
Arithmetic
Instruction | Type of Input | Note |
ADD | ADD (S1) (S2) (D) | Adds Data S1 To Data S2, And Stores The Result In Device D. |
ADDP | ADDP (S1) (S2) (D) | Adds Data S1 To Data S2, And Stores The Result In Device D. |
SUB | SUB (S1) (S2) (D) | Subtracts Data In S2 From Data In S1 And Stores The Result In Device D. |
SUBP | SUBP (S1) (S2) (D) | Subtracts Data In S2 From Data In S1 And Stores The Result In Device D. |
MUL | MUL (S1) (S2) (D) | Multiplies Data In S1 By Data In S2 And Stores The Result In D. |
MULP | MULP (S1) (S2) (D) | Multiplies Data In S1 By Data In S2 And Stores The Result In D. |
DIV | DIV (S1) (S2) (D) | Divides Data In S1 By Data In S2 And Stores The Resutl In Device D. |
DIVP | DIVP (S1) (S2) (D) | Divides Data In S1 By Data In S2 And Stores The Resutl In Device D. |
WMUL | WMUL (S1) (S2) (D) | Multiplies BIN 32-bit data designated by S1, S1+1 and BIN 32-bit data designated by S2, S2+1 and stores the result in the device designated by D, D+1. |
WMULP | WMULP (S1) (S2) (D) | Multiplies BIN 32-bit data designated by S1, S1+1 and BIN 32-bit data designated by S2, S2+1 and stores the result in the device designated by D, D+1. |
WDIV | WDIV (S1) (S2) (D) | This is used to divide the double data in the device assigned to S1, S1+1 by the DOUBLE data in the device assigned to S2, S2+1 storing the quotient of the result in the device assigned to D |
WDIVP | WDIVP (S1) (S2) (D) | This is used to divide the double data in the device assigned to S1, S1+1 by the DOUBLE data in the device assigned to S2, S2+1 storing the quotient of the result in the device assigned to D |
WSUM | WSUM (S) (D) (n) | Summed up all 16bit binary data for n words from the device designated at S, and stored it in the device designated at D |
WSUMP | WSUMP (S) (D) (n) | Summed up all 16bit binary data for n words from the device designated at S, and stored it in the device designated at D |
Arithmetic (DWORD)
Instruction | Type of Input | Note |
DADD | DADD (S1) (S2) (D) | Adds Double- Word Data In S2 To Double-Word Data In S1 And Stores The Result In Device D. |
DADDP | DADDP (S1) (S2) (D) | Adds Double- Word Data In S2 To Double-Word Data In S1 And Stores The Result In Device D. |
DSUB | DSUB (S1) (S2) (D) | Subtract Double- Word Data In S2 From Double-Word Data In S1 And Stores The result In D. |
DSUBP | DSUBP (S1) (S2) (D) | Subtract Double- Word Data In S2 From Double-Word Data In S1 And Stores The result In D. |
DMUL | DMUL (S1) (S2) (D) | Multiplies Double-Word Data In S1 By Double-Word Data In S2 And Stores The Result In D. |
DMULP | DMULP (S1) (S2) (D) | Multiplies Double-Word Data In S1 By Double-Word Data In S2 And Stores The Result In D. |
DDIV | DDIV (S1) (S2) (D) | Divides Double-Word Data In S1 By Double-Word Data In S2 And Stores The Result In Device D. |
DDIVP | DDIVP (S1) (S2) (D) | Divides Double-Word Data In S1 By Double-Word Data In S2 And Stores The Result In Device D. |
DWMUL | WMUL (S1) (S2) (D) | Multiplies BIN 32-bit data designated by S1, S1+1 and BIN 32-bit data designated by S2, S2+1 and stores the result in the device designated by D, D+1. |
DWMULP | WMULP (S1) (S2) (D) | Multiplies BIN 32-bit data designated by S1, S1+1 and BIN 32-bit data designated by S2, S2+1 and stores the result in the device designated by D, D+1. |
DWDIV | WDIV (S1) (S2) (D) | This is used to divide the double data in the device assigned to S1, S1+1 by the DOUBLE data in the device assigned to S2, S2+1 storing the quotient of the result in the device assigned to D |
DWDIVP | WDIVP (S1) (S2) (D) | This is used to divide the double data in the device assigned to S1, S1+1 by the DOUBLE data in the device assigned to S2, S2+1 storing the quotient of the result in the device assigned to D |
Arithmetic (BCD)
Instruction | Type of Input | Note |
BADD | BADD (S1) (S2) (D) | Adds 4 Digits BCD Data In S1 To 4 Digits BCD Data In S2, And Stores The Result In Device D. |
BADDP | BADDP (S1) (S2) (D) | Adds 4 Digits BCD Data In S1 To 4 Digits BCD Data In S2, And Stores The Result In Device D. |
BSUB | BSUB (S1) (S2) (D) | Subtracts 4 Digits BCD Data In S2 From 4 Digits BCD Data In S1 And Stores The Result In Device D. |
BSUBP | BSUBP (S1) (S2) (D) | Subtracts 4 Digits BCD Data In S2 From 4 Digits BCD Data In S1 And Stores The Result In Device D. |
BMUL | BMUL (S1) (S2) (D) | Mutiplies 4 Digits BCD Data In S1 By 4 Digits BCD Data In S2. |
BMULP | BMULP (S1) (S2) (D) | Mutiplies 4 Digits BCD Data In S1 By 4 Digits BCD Data In S2. |
BDIV | BDIV (S1) (S2) (D) | Divides 4 Digits BCD Data In S1 By 4 Digits BCD Data In S2 And Stores The Result In Device D. |
BDIVP | BDIVP (S1) (S2) (D) | Divides 4 Digits BCD Data In S1 By 4 Digits BCD Data In S2 And Stores The Result In Device D. |
Arithmetic (BCD, DWORD)
Instruction | Type of Input | Note |
DBADD | DBADD (S1) (S2) (D) | Adds 4 Digits BCD Double-Word Data In S2 To 4 Digits BCD Double-Word Data In S1 And Stores The Result In Device D. |
DBADDP | DBADDP (S1) (S2) (D) | Adds 4 Digits BCD Double-Word Data In S2 To 4 Digits BCD Double-Word Data In S1 And Stores The Result In Device D. |
DBSUB | DBSUB (S1) (S2) (D) | Subtracts 8 Digits BCD Data In S2 From 8 Digits BCD Data In S1. |
DBSUBP | DBSUBP (S1) (S2) (D) | Subtracts 8 Digits BCD Data In S2 From 8 Digits BCD Data In S1. |
DBMUL | DBMUL (S1) (S2) (D) | Multiplies 8 Digits BCD Data In S1 By 8 Digits BCD Data In S2. |
DBMULP | DBMULP (S1) (S2) (D) | Multiplies 8 Digits BCD Data In S1 By 8 Digits BCD Data In S2. |
DBDIV | DBDIV (S1) (S2) (D) | Divides 8 Digits BCD Data In S1 By 8 Digits BCD Data And Stores The Result In Device D. |
DBDIVP | DBDIVP (S1) (S2) (D) | Divides 8 Digits BCD Data In S1 By 8 Digits BCD Data And Stores The Result In Device D. |
Arithmetic (Floating decimal point, XP)
Instruction | Type of Input | Note |
EADD | EADD (S1) (S2) (D) | This is used to add the floating-point data in the device assigned to S1 to the floating-point data in the device assigned to S2, storing the result in the device assigned D. |
EADDP | EADDP (S1) (S2) (D) | This is used to add the floating-point data in the device assigned to S1 to the floating-point data in the device assigned to S2, storing the result in the device assigned D. |
ESUB | ESUB (S1) (S2) (D) | This is used to subtract the Floating-point data in the device assigned to S2 from the Floating-point data in the device assigned to S1, storing the result in the device assigned to D. |
ESUBP | ESUBP (S1) (S2) (D) | This is used to subtract the Floating-point data in the device assigned to S2 from the Floating-point data in the device assigned to S1, storing the result in the device assigned to D. |
EMUL | EMUL (S1) (S2) (D) | This is used to multiply the Floating-point data assigned to S1 by the Floating-point data in the device assigned to S2, storing the result in the device assigned to D. |
EMULP | EMULP (S1) (S2) (D) | This is used to multiply the Floating-point data assigned to S1 by the Floating-point data in the device assigned to S2, storing the result in the device assigned to D. |
EDIV | EDIV (S1) (S2) (D) | This is used to divide the floating-point data in the device assigned to S1 to the floating-point data in the device assigned to S2, storing the result in the device assigned D. |
EDIVP | EDIVP (S1) (S2) (D) | This is used to divide the floating-point data in the device assigned to S1 to the floating-point data in the device assigned to S2, storing the result in the device assigned D. |
INC / DEC
Instruction | Type of Input | Note |
INC | INC (D) | Adds 1 To Data Value In D And Stores The Result In D Again. |
INCP | INCP (D) | Adds 1 To Data Value In D And Stores The Result In D Again. |
DINC | DINC (D) | Adds 1 To Double-Word Data Value In D And Stores The Result In D Again. |
DINCP | DINCP (D) | Adds 1 To Double-Word Data Value In D And Stores The Result In D Again. |
DEC | DEC (D) | Subtracts 1 From Data Value In D And Stores The Result In Device D Again. |
DECP | DECP (D) | Subtracts 1 From Data Value In D And Stores The Result In Device D Again. |
DDEC | DDEC (D) | Subtracts 1 From Double-Word Data Value In D And Stores The Result In Device D Again. |
DDECP | DDECP (D) | Subtracts 1 From Double-Word Data Value In D And Stores The Result In Device D Again. |
Complement
Instruction | Type of Input | Note |
NEG | NEG (D) | Sign-Inverts Contents Of Data In D And Stores The Result In D Again. |
NEGP | NEGP (D) | Sign-Inverts Contents Of Data In D And Stores The Result In D Again. |
DNEG | DNEG (D) | Sign-Inverts Contents Of Double-Word Data In D And Stores The Result In D Again. |
DNEGP | DNEGP (D) | Sign-Inverts Contents Of Double-Word Data In D And Stores The Result In D Again. |
MIN / MAX
Instruction | Type of Input | Note |
MAX | MAX (S) (D) (n) | Stores The Biggest Value Among n Pieces Of Data From Data In S, Its Location And Number Of The Values In D. |
MAXP | MAXP (S) (D) (n) | Stores The Biggest Value Among n Pieces Of Data From Data In S, Its Location And Number Of The Values In D. |
MIN | MIN (S) (D) (n) | Stores The Smallest Value Among n Pieces Of Data From Data In S, Its Location And Number Of The Values In D. |
MINP | MINP (S) (D) (n) | Stores The Smallest Value Among n Pieces Of Data From Data In S, Its Location And Number Of The Values In D. |
DMAX | DMAX (S) (D) (n) | Stores The Biggest Value Among n Pieces Of Data From Double-Word Data Of S, Its Location And Number Of The Values In D. |
DMAXP | DMAXP (S) (D) (n) | Stores The Biggest Value Among n Pieces Of Data From Double-Word Data Of S, Its Location And Number Of The Values In D. |
DMIN | DMIN (S) (D) (n) | Stores The Smallest Value Among n Pieces Of Data From Double-Word Data Of S, Its Location And Number Of The Values In D. |
DMINP | DMINP (S) (D) (n) | Stores The Smallest Value Among n Pieces Of Data From Double-Word Data Of S, Its Location And Number Of The Values In D. |
Transmit Data
Instruction | Type of Input | Note |
MOV | MOV (S) (D) | Transmits Word Data In Device S To Device D. |
MOVP | MOVP (S) (D) | Transmits Word Data In Device S To Device D. |
DMOV | DMOV (S) (D) | Transmits Double-Word Data In Device S To Device D. |
DMOVP | DMOVP (S) (D) | Transmits Double-Word Data In Device S To Device D. |
CML | CML (S) (D) | Inverts Each Bit Of Data In Device S And Stores The Result In Device D. |
CMLP | CMLP (S) (D) | Inverts Each Bit Of Data In Device S And Stores The Result In Device D. |
DCML | DCML (S) (D) | Inverts Each Bit Of Double-Word Data In S And Stores The Result In Device D. |
DCMLP | DCMLP (S) (D) | Inverts Each Bit Of Double-Word Data In S And Stores The Result In Device D. |
BMOV | BMOV (S) (D) (n) | Transmits n Pieces Of Data In S To Device D. |
BMOVP | BMOVP (S) (D) (n) | Transmits n Pieces Of Data In S To Device D. |
FMOV | FMOV (S) (D) (n) | Transmits Data In S To n Pieces Of Device From Device D In Due Order. |
FMOVP | FMOVP (S) (D) (n) | Transmits Data In S To n Pieces Of Device From Device D In Due Order. |
WBMOV | WBMOV (S) (D) (fm) | transfer bit data from S to D, obey fm |
WBMOVP | WBMOVP (S) (D) (fm) | transfer bit data from S to D, obey fm |
Exchange Data
Instruction | Type of Input | Note |
XCH | XCH (D1) (D2) | Exchanges Word Data In S With Word Data In D. |
XCHP | XCHP (D1) (D2) | Exchanges Word Data In S With Word Data In D. |
DXCH | DXCH (S) (D) | Exchanges Double-Word Data In S With Double-Word Data In D Each Other. |
DXCHP | DXCHP (S) (D) | Exchanges Double-Word Data In S With Double-Word Data In D Each Other. |
BXCH | BXCH (D1) (D2) (n) | Exchanges n Pieces Of Data In Device S And n Pieces Of Data In Device D Each Other. |
BXCHP | BXCHP (D1) (D2) (n) | Exchanges n Pieces Of Data In Device S And n Pieces Of Data In Device D Each Other. |
SWAP | SWAP (D) | Exchanges The Upper Byte Of Data In D With The Lower Byte Of It And Stores The Result In Device D. |
SWAPP | SWAPP (D) | Exchanges The Upper Byte Of Data In D With The Lower Byte Of It And Stores The Result In Device D. |
Logical
Instruction | Type of Input | Note |
WAND | WAND (S1) (S2) (D) | AND-Operates Data In S1 And Data In S2, And Stores In Device D. |
WANDP | WANDP (S1) (S2) (D) | AND-Operates Data In S1 And Data In S2, And Stores In Device D. |
WOR | WOR (S1) (S2) (D) | OR-Operates Data In S1 And Data In S2, And Stores The Result In Device D. |
WORP | WORP (S1) (S2) (D) | OR-Operates Data In S1 And Data In S2, And Stores The Result In Device D. |
WXOR | WXOR (S1) (S2) (D) | Exclusive - OR-Operates Data In S1 And Data In S2, And Stores The Result In D. |
WXORP | WXORP (S1) (S2) (D) | Exclusive - OR-Operates Data In S1 And Data In S2, And Stores The Result In D. |
WXNR | WXNR (S1) (S2) (D) | Exclusive - NOR-Operates Data In S1 And Data In S2, And Stores The Result In D. |
WXNRP | WXNRP (S1) (S2) (D) | Exclusive - NOR-Operates Data In S1 And Data In S2, And Stores The Result In D. |
Logical (DWORD)
Instruction | Type of Input | Note |
DAND | DAND (S1) (S2) (D) | AND-Operates Data In Device S1 And Data In Device S2, And Stores The Result In Device D. |
DANDP | DANDP (S1) (S2) (D) | AND-Operates Data In Device S1 And Data In Device S2, And Stores The Result In Device D. |
DOR | DOR (S1) (S2) (D) | OR-Operates Data In S1 And 32 Bit Data In S2, And Stores The Result In D. |
DORP | DORP (S1) (S2) (D) | OR-Operates Data In S1 And 32 Bit Data In S2, And Stores The Result In D. |
DXOR | DXOR (S1) (S2) (D) | Exclusive - OR-Operates Double-Word Data In S1 And Double-Word Data In S2, And Stores The Result In D. |
DXORP | DXORP (S1) (S2) (D) | Exclusive - OR-Operates Double-Word Data In S1 And Double-Word Data In S2, And Stores The Result In D. |
DXNR | DXNR (S1) (S2) (D) | Exclusive - NOR-Operates Double-Word Data In S1 And Double-Word Data In S2, And Stores The Result In D. |
DXNRP | DXNRP (S1) (S2) (D) | Exclusive - NOR-Operates Double-Word Data In S1 And Double-Word Data In S2, And Stores The Result In D. |
Logical (Block)
Instruction | Type of Input | Note |
BKAND | BKAND (S1) (S2) (D) (n) | AND-Operates n Pieces Of Data In Device S1 And n Pieces OF Data In Device S2, And Stores The Result In Device D. |
BKANDP | BKANDP (S1) (S2) (D) (n) | AND-Operates n Pieces Of Data In Device S1 And n Pieces OF Data In Device S2, And Stores The Result In Device D. |
BKOR | BKOR (S1) (S2) (D) (n) | OR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
BKORP | BKORP (S1) (S2) (D) (n) | OR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
BKXOR | BKXOR (S1) (S2) (D) (n) | Exclusive - OR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
BKXORP | BKXORP (S1) (S2) (D) (n) | Exclusive - OR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
BKXNR | BKXNR (S1) (S2) (D) (n) | Exclusive - NOR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
BKXNRP | BKXNRP (S1) (S2) (D) (n) | Exclusive - NOR-Operates n Pieces Of Data In S1 And n Pieces Of Data In S2, And Stores The Result In Device D. |
Rotation
Instruction | Type of Input | Note |
ROL | ROL (D) (n) | Shifts Left 16 Pieces Of Bit In D As Much As n Bits. Shifts The Uppermost Bit To The Lowest Bit And Carry Flag. |
ROLP | ROLP (D) (n) | Shifts Left 16 Pieces Of Bit In D As Much As n Bits. Shifts The Uppermost Bit To The Lowest Bit And Carry Flag. |
ROR | ROR (D) (n) | Shifts Right 16 Pieces Of Bit In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag To The Uppermost Bit. |
RORP | RORP (D) (n) | Shifts Right 16 Pieces Of Bit In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag To The Uppermost Bit. |
Rotation (Carry)
Instruction | Type of Input | Note |
RCL | RCL (D) (n) | Shifts Left 16 Pieces Of Bit In D As Much As n Bits. Shifts The Uppermost Bit To Carry Flag And Carry Flag To The Lowest Bit. |
RCLP | RCLP (D) (n) | Shifts Left 16 Pieces Of Bit In D As Much As n Bits. Shifts The Uppermost Bit To Carry Flag And Carry Flag To The Lowest Bit. |
RCR | RCR (D) (n) | Shifts Right 16 Pieces Of Bit In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag. |
RCRP | RCRP (D) (n) | Shifts Right 16 Pieces Of Bit In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag. |
Rotation (DWORD)
Instruction | Type of Input | Note |
DROL | DROL (D) (n) | Shifts Left 32 Bits In D As Much As n Bits. Shifts The Uppermost Bit To The Lowest Bit And Carry Flag. |
DROLP | DROLP (D) (n) | Shifts Left 32 Bits In D As Much As n Bits. Shifts The Uppermost Bit To The Lowest Bit And Carry Flag. |
DROR | DROR (D) (n) | Shifts Right 32 Bits In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag To The Uppermost Bit. |
DRORP | DRORP (D) (n) | Shifts Right 32 Bits In D As Much As n Bits. Shifts The Lowest Bit To Carry Flag And Carry Flag To The Uppermost Bit. |
Rotation (DWORD, Carry)
Instruction | Type of Input | Note |
DRCL | DRCL (D) (n) | Shifts Left 32 Bits In D As Much As n Bits. Shifts The Uppermost Bit To Carry Flag And Carry Flag To The Lowest Bit. |
DRCLP | DRCLP (D) (n) | Shifts Left 32 Bits In D As Much As n Bits. Shifts The Uppermost Bit To Carry Flag And Carry Flag To The Lowest Bit. |
DRCR | DRCR (D) (n) | Shifts Right 32 Bits In D As Much As n Bits. Shifts The Lowest Bit To The Uppermost Bit And Carry Flag. |
DRCRP | DRCRP (D) (n) | Shifts Right 32 Bits In D As Much As n Bits. Shifts The Lowest Bit To The Uppermost Bit And Carry Flag. |
Shift
Instruction | Type of Input | Note |
SFL | SFL (D) (n) | Shifts Left Data Bit In D As Much As n Bits. Fills Lower n Bits With 0 And Stores the Result In D. |
SFLP | SFLP (D) (n) | Shifts Left Data Bit In D As Much As n Bits. Fills Lower n Bits With 0 And Stores the Result In D. |
SFR | SFR (D) (n) | Shifts Right Data Bit In D As Much As n Bits. Fills Upperr n Bits With 0 And Stores the Result In D. |
SFRP | SFRP (D) (n) | Shifts Right Data Bit In D As Much As n Bits. Fills Upperr n Bits With 0 And Stores the Result In D. |
Shift (BIT)
Instruction | Type of Input | Note |
BSFL | BSFL (D) (n) | n Pieces Of Data Are Shifted Left From Data In Device D And The Shifted Lowest Data Is Filled With 0. |
BSFLP | BSFLP (D) (n) | n Pieces Of Data Are Shifted Left From Data In Device D And The Shifted Lowest Data Is Filled With 0. |
BSFR | BSFR (D) (n) | n Pieces Of Data Are Shifted Right From Data In Device D And The Shifted Uppermost Data Is Filled With 0. |
BSFRP | BSFRP (D) (n) | n Pieces Of Data Are Shifted Right From Data In Device D And The Shifted Uppermost Data Is Filled With 0. |
Shift (WORD)
Instruction | Type of Input | Note |
DSFL | DSFL (D) (n) | Shifts Left Double-Word Data Bits In D As Much As n Bits. Fills Lower n Bits With 0 And Stores Them In D. |
DSFLP | DSFLP (D) (n) | Shifts Left Double-Word Data Bits In D As Much As n Bits. Fills Lower n Bits With 0 And Stores Them In D. |
DSFR | DSFR (D) (n) | Shifts Right Double-Word Data Bits In D As Much As n Bits. Fills Upper n Bits With 0 And Stores Them In D. |
DSFRP | DSFRP (D) (n) | Shifts Right Double-Word Data Bits In D As Much As n Bits. Fills Upper n Bits With 0 And Stores Them In D. |
Conversion (BIN -> BCD)
Instruction | Type of Input | Note |
BCD | BCD (S) (D) | Converts BIN Data Value In S To BCD Data And Stores The Result In Device D. |
BCDP | BCDP (S) (D) | Converts BIN Data Value In S To BCD Data And Stores The Result In Device D. |
DBCD | DBCD (S) (D) | Converts BIN DOuble-Word Data Value In S To BCD Double-Word Data And Stores The Result In Device D. |
DBCDP | DBCDP (S) (D) | Converts Double-Word BIN Data Value In S To BCD Data And Stores The result In Device D. |
Conversion (BCD -> BIN)
Instruction | Type of Input | Note |
BIN | BIN (S) (D) | Converts 4 Digits BCD Data Value In S To BIN Data And Stores The Result In Device D. |
BINP | BINP (S) (D) | Converts 4 Digits BCD Data Value In S To BIN Data And Stores The Result In Device D. |
DBIN | DBIN (S) (D) | Converts 8 Digits BCD Data Value In S To BIN Data And Stores The Result In Device D. |
DBINP | DBINP (S) (D) | Converts 8 Digits BCD Data Value In S To BIN Data And Stores The Result In Device D. |
Conversion (BIN -> ASCII)
Instruction | Type of Input | Note |
BINDA | BINDA (S) (D) | Converts BIN Data In S To Decimal ASCII Code And Stores The Result In Device D. |
BINDAP | BINDAP (S) (D) | Converts BIN Data In S To Decimal ASCII Code And Stores The Result In Device D. |
DBINDA | DBINDA (S) (D) | Converts BIN Data In S To Decimal ASCII Code And Stores The Result In Device D. |
DBINDAP | DBINDAP (S) (D) | Converts BIN Data In S To Decimal ASCII Code And Stores The Result In Device D. |
Conversion (ASCII -> BIN)
Instruction | Type of Input | Note |
DABIN | DABIN (S) (D) | Converts Decimal ASCII Code In Device S To 16bit BIN Data And Stores The Result In Device D. |
DABINP | DABINP (S) (D) | Converts Decimal ASCII Code In Device S To 16bit BIN Data And Stores The Result In Device D. |
DDABIN | DDABIN (S) (D) | Converts Decimal ASCII Code In S To 32 Bit BIN Data And Stores The Result In Device D. |
DDABINP | DDABINP (S) (D) | Converts Decimal ASCII Code In S To 32 Bit BIN Data And Stores The Result In Device D. |
Conversion ( BIN -> HEX ASCII)
Instruction | Type of Input | Note |
BINHA | BINHA (S) (D) | Converts BIN Data In S To Hexadecimal ASCII Code And Stores The Result In Device D. |
BINHAP | BINHAP (S) (D) | Converts BIN Data In S To Hexadecimal ASCII Code And Stores The Result In Device D. |
DBINHA | DBINHA (S) (D) | Converts BIN Data In S To Hexadecimal ASCII Code And Stores The Result In D. |
DBINHAP | DBINHAP (S) (D) | Converts BIN Data In S To Hexadecimal ASCII Code And Stores The Result In D. |
Conversion (HEX ASCII -> BIN)
Instruction | Type of Input | Note |
HABIN | HABIN (S) (D) | Converts Hexadecimal ASCII COde In S To 16 Bit BIN Data And Stores The Result In D. |
HABINP | HABINP (S) (D) | Converts Hexadecimal ASCII COde In S To 16 Bit BIN Data And Stores The Result In D. |
DHABIN | DHABIN (S) (D) | Converts Hexadecimal ASCII Code In S To 32 BIt BIN Data And Stores The Result In Device D. |
DHABINP | DHABINP (S) (D) | Converts Hexadecimal ASCII Code In S To 32 BIt BIN Data And Stores The Result In Device D. |
Conversion (BCD -> ASCII)
Instruction | Type of Input | Note |
BCDDA | BCDDA (S) (D) | Converts 4 Digits BCD Data In S To Decimal ASCII Code And Stores The Result In Device D. |
BCDDAP | BCDDAP (S) (D) | Converts 4 Digits BCD Data In S To Decimal ASCII Code And Stores The Result In Device D. |
DBCDDA | DBCDDA (S) (D) | Converts 8 Digits BCD Data In S To Decimal ASCII Code And Stores The Result In Device D. |
DBCDDAP | DBCDDAP (S) (D) | Converts 8 Digits BCD Data In S To Decimal ASCII Code And Stores The Result In Device D. |
Conversion (Floating decimal point, XP)
Instruction | Type of Input | Note |
FLT | FLT (S) (D) | Converts 16-bit BIN data designated by S to floating decimal point real number, and stores at device number designated by D . |
FLTP | FLTP (S) (D) | Converts 16-bit BIN data designated by S to floating decimal point real number, and stores at device number designated by D . |
DFLT | DFLT (S) (D) | Converts 32-bit BIN data designated by S to floating decimal point real number, and stores at device number designated by D |
DFLTP | DFLTP (S) (D) | Converts 32-bit BIN data designated by S to floating decimal point real number, and stores at device number designated by D |
INT | INT (S) (D) | Converts the floating decimal point real number designated at S into BIN 16-bit data and stores it at the device number designated at D |
INTP | INTP (S) (D) | Converts the floating decimal point real number designated at S into BIN 16-bit data and stores it at the device number designated at D |
RAD | RAD (S) (D) | Converts units of angle size from angle units designated by S to radian units, and stores result at device number designated by D. |
RADP | RADP (S) (D) | Converts units of angle size from angle units designated by S to radian units, and stores result at device number designated by D. |
DEG | DEG (S) (D) | Converts Unit of angle size from radian units designated by S to angles, and stores result at device number designated by D. |
DEGP | DEGP (S) (D) | Converts Unit of angle size from radian units designated by S to angles, and stores result at device number designated by D. |
EMOV | EMOV (S) (D) | This is used to transfer the Floating-point data in the device assigned to S to the device assigned to D. |
EMOVP | EMOVP (S) (D) | This is used to transfer the Floating-point data in the device assigned to S to the device assigned to D. |
Decode / Encode
Instruction | Type of Input | Note |
DECO | DECO (S) (D) (n) | Decodes Lower n Bits In S And Sets The Contact Corresponding To Result Of Device D. |
DECOP | DECOP (S) (D) (n) | Decodes Lower n Bits In S And Sets The Contact Corresponding To Result Of Device D. |
ENCO | ENCO (S) (D) (n) | Encodes The Uppermost Bit Location Which Is Set As 1 In 2^n Of S And Stores The Result In D In Numerical Value Data. |
ENCOP | ENCOP (S) (D) (n) | Encodes The Uppermost Bit Location Which Is Set As 1 In 2^n Of S And Stores The Result In D In Numerical Value Data. |
7 Segment
Instruction | Type of Input | Note |
SEG | SEG (S) (D) | Decodes n Pieces Of Number From Start Bit In S As 7 Segment By The Set Format And Stores The Result In D. |
SEGP | SEGP (S) (D) | Decodes n Pieces Of Number From Start Bit In S As 7 Segment By The Set Format And Stores The Result In D. |
Union / Disunion
Instruction | Type of Input | Note |
DIS | DIS (S) (D) (n) | Stores n(n=1 Means 4 Bits) Pieces Of Numerical Value Data From S In Lower Bit As Much As n From D Each. |
DISP | DISP (S) (D) (n) | Stores n(n=1 Means 4 Bits) Pieces Of Numerical Value Data From S In Lower Bit As Much As n From D Each. |
UNI | UNI (S) (D) (n) | Combines Each Lower 4 Bits Of n(n=1 Means 4 Bits) Pieces Of Data In S, And Stores the Result In Device D. |
UNIP | UNIP (S) (D) (n) | Combines Each Lower 4 Bits Of n(n=1 Means 4 Bits) Pieces Of Data In S, And Stores the Result In Device D. |
BIT
Instruction | Type of Input | Note |
TEST | TEST (S1) (S2) (D) | Stores Bit Of The Assigned Order Among Data Bits In S1. If The Result Is 1, Sets. If 0, Resets. |
TESTP | TESTP (S1) (S2) (D) | Stores Bit Of The Assigned Order Among Data Bits In S1. If The Result Is 1, Sets. If 0, Resets. |
DTEST | DTEST (S1) (S2) (D) | Stores The Bit Of Order Assigned to S2 In Double-Word Data Bit Of S1 In D. If It Is 1, Sets. If 0, Resets. |
DTESTP | DTESTP (S1) (S2) (D) | Stores The Bit Of Order Assigned to S2 In Double-Word Data Bit Of S1 In D. If It Is 1, Sets. If 0, Resets. |
BSET | BSET (D) (n) | Sets nth Bit In Data Bits In Device D. |
BSETP | BSETP (D) (n) | Sets nth Bit In Data Bits In Device D. |
BRST | BRST (D) (n) | Resets nth Bit in Word Data Bits In Device D. |
BRSTP | BRSTP (D) (n) | Resets nth Bit in Word Data Bits In Device D. |
BITMOV | BITMOV (S) (D) (n) | Sends the data in the device assigned to S as much as n bits from the start device number in the device assigned to D. |
BITMOVP | BITMOVP (S) (D) (n) | Sends the data in the device assigned to S as much as n bits from the start device number in the device assigned to D. |
ANDBT | ANDBT (S1) (S2) | AND-Operates the bit of the order assigned to S2 in the word device data assigned to S1 and Contact A. |
ANDBTI | ANDBTI (S1) (S2) |
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LDBT | LDBT (S1) (S2) | LD-Operates the bit of the order assigned to S2 in the word device data assigned to S1 and Contact A. |
LDBTI | LDBTI (S1) (S2) |
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ORBT | ORBT (S1) (S2) | OR-Operates the bit of the order assigned to S2 in the word device data assigned to S1 and Contact A. |
ORBTI | ORBTI (S1) (S2) |
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SUM | SUM (S) (D) | Counts Number Of Bit Data Which Are Set As 1 In Data Of S And Stores The Number. |
SUMP | SUMP (S) (D) | Counts Number Of Bit Data Which Are Set As 1 In Data Of S And Stores The Number. |
DSUM | DSUM (S) (D) | Counts Number Of Bit Data Which Are Set As 1 In Double-Word Data Of S And Stores The Number. |
DSUMP | DSUMP (S) (D) | Counts Number Of Bit Data Which Are Set As 1 In Double-Word Data Of S And Stores The Number. |
TIME
Instruction | Type of Input | Note |
DATE+ | DATE+ (S1) (S2) (D) | Adds Hour, Minute And Second Data In S2 To Hour, Minute And Second Data In S1 Each Other, And Stores The Result In D In Due Order. |
DATE+P | DATE+P (S1) (S2) (D) | Adds Hour, Minute And Second Data In S2 To Hour, Minute And Second Data In S1 Each Other, And Stores The Result In D In Due Order. |
DATE- | DATE- (S1) (S2) (D) | Subtrats Hour, Minute And Second Data In S2 From Hour, Minute And Second Data In S1 Each Other, And Stores The Result In D In Due Order. |
DATE-P | DATE-P (S1) (S2) (D) | Subtrats Hour, Minute And Second Data In S2 From Hour, Minute And Second Data In S1 Each Other, And Stores The Result In D In Due Order. |
SECOND | SECOND (S) (D) | Converts Hour, Minute And Second Data In S To Second Data Each And Stores The Result In D. |
SECONDP | SECONDP (S) (D) | Converts Hour, Minute And Second Data In S To Second Data Each And Stores The Result In D. |
HOUR | HOUR (S) (D) | Converts Second Data In S To Hour, Minute And Second Data And Stores The Result In D In Due Order. |
HOURP | HOURP (S) (D) | Converts Second Data In S To Hour, Minute And Second Data And Stores The Result In D In Due Order. |
DATERD | DATERD (D) | Reads Year, Month, Day, Hour, Minute, Second And Day Of Week Data From CPU Clock Device And Stores Them In Device D In Due Order. |
DATERDP | DATERDP (D) | Reads Year, Month, Day, Hour, Minute, Second And Day Of Week Data From CPU Clock Device And Stores Them In Device D In Due Order. |
DATEWR | DATEWR (S) | Year, Month, Day, Hour, Minute, Second And Day Of Week Data In S Are Written In CPU Clock Device. |
DATEWRP | DATEWRP (S) | Year, Month, Day, Hour, Minute, Second And Day Of Week Data In S Are Written In CPU Clock Device. |
Timer
Instruction | Type of Input | Note |
TON | TON (S) (t) | If Curren Value Is Increased And Reaches Set Value, Timer Contact Is Set. |
TOFF | TOFF (S) (t) | When Input Condition Is Off, The Set Value Is Subtracted. If Current Value Reaches 0, Output Is Reset. |
TMR | TMR (S) (t) | Though Current Value Is Increased And Input Is On-Off Reapeatly, If The Current Value Is Accumulated Whenever It Is On And Reaches Set Time, Timer Contact Is Set. |
TMON | TMON (S) (t) | Though Output Is Set And Input Is Set-Reset Repeatly, If Current Value Is Subtracted Whenever It Is Set And Reaches 0, Timer Output Is Reset. |
TRTG | TRTG (S) (t) | If Output Is Set And Current Value Is Subtracted To Reach 0, Output Is Reset. If Output Is Reset Before Current Value Is 0, Current Value Is Set Up As Set Value. |
Counter
Instruction | Type of Input | Note |
CTU | CTU (S) (t) | Adds One By One To Current Value Whenever Pulse Is Input. If Current Value Is Over Set Value, Sets Output And Counts Up To Maximum Of Counter. |
CTD | CTD (S) (t) | Subtracts One By One From Set Value Whenever Rising Edge Is Input. If The Value Is 0, Sets Output. |
CTUD | CTUD (S) (t) | Adds One By One Whenever Pulse Is Input To Up Terminal. Substracts One By One Whenever Pulse Is Input To Down Terminal. If Current Value Is Over Set Value, Sets Output. |
CTR | CTR (S) (t) | Adds One By One Whenever Pulse Is Input. If The Value Reaches Set Value, Sets Output. If Input Signal Is On From Off, Current Value Is Increased From 0. |
Read / Write
Instruction | Type of Input | Note |
FROM | FROM (n1) (n2) (D) (n3) | Reads n3 Pieces Of Word Data In User Program Memory n2 Of Optional Card n1(SLot Number) And Stores The Result In D. |
FROMP | FROMP (n1) (n2) (D) (n3) | Reads n3 Pieces Of Word Data In User Program Memory n2 Of Optional Card n1(SLot Number) And Stores The Result In D. |
DFRO | DFRO (n1) (n2) (D) (n3) | Reads n3 Pieces Of Double-Word Data In User Program Memory n2 Of Optional Card n1(Slot Number) And Stores Them In Device D. |
DFROP | DFROP (n1) (n2) (D) (n3) | Reads n3 Pieces Of Double-Word Data In User Program Memory n2 Of Optional Card n1(Slot Number) And Stores Them In Device D. |
TO | TO (n1) (n2) (S) (n3) | Writes n3 Pieces Data In S To User Program Memory n2 Of Opetional Card n1(Slot Numer). |
TOP | TOP (n1) (n2) (S) (n3) | Writes n3 Pieces Data In S To User Program Memory n2 Of Opetional Card n1(Slot Numer). |
DTO | DTO (n1) (n2) (S) (n3) | Writes n3 Pieces Of Double-Word Data In S To User Program Memory n2 Of Optional Card n1(Slot Number). |
DTOP | DTOP (n1) (n2) (S) (n3) | Writes n3 Pieces Of Double-Word Data In S To User Program Memory n2 Of Optional Card n1(Slot Number). |
FREAD | FREAD (n1) (n2) (D) (n3) (n4) | Read n3 words of data from the address designated by n2 ofthe system memory of the special function module designated by n1. Then, stores the data in the area starting from the device designated by D. The result of instruction is stored to the device designated by n3. |
FREADP | FREADP (n1) (n2) (D) (n3) (n4) | Read n3 words of data from the address designated by n2 ofthe system memory of the special function module designated by n1. Then, stores the data in the area starting from the device designated by D. The result of instruction is stored to the device designated by n3. |
FWRITE | FWRITE (n1) (n2) (D) (n3) (n4) | Write n3 words of data from the device designated by D to the area starting from the address designated by n2 of the system memory of the special function module designated by n1. |
FWRITEP | FWRITEP (n1) (n2) (D) (n3) (n4) | Write n3 words of data from the device designated by D to the area starting from the address designated by n2 of the system memory of the special function module designated by n1. |
Communication
Instruction | Type of Input | Note |
SND | SND (Slot)(S)(Size)(Result) | Transmits Data In Device Of Master Atation To Device Of Slave Station. |
SNDP | SNDP (Slot)(S)(Size)(Result) | Transmits Data In Device Of Master Atation To Device Of Slave Station. |
RCV | RCV (Slot)(D)(Size)(Result) | Reads And Brings Data In Slave Station To Device Of Master Station. |
RCVP | RCVP (Slot)(D)(Size)(Result) | Reads Data In Slave Station To Device Of Master Station. |
Communication (SPC Program)
Instruction | Type of Input | Note |
RECV | RECV (PID) (F_Name) (Result) | Compares the data received from master station with the data(F_Name) set up by Special Function Program(PID), storing them in the assigned device. |
RECVP | RECVP (PID) (F_Name) (Result) | Compares the data received from master station with the data(F_Name) set up by Special Function Program(PID), storing them in the assigned device. |
SEND | SEND (PID) (F_Name) (Result) | Sends the data(F_Name) set up by Special Function Program(PID) from master station to the device of slave station. |
SENDP | SENDP (PID) (F_Name) (Result) | Sends the data(F_Name) set up by Special Function Program(PID) from master station to the device of slave station. |
Watch Dog Time
Instruction | Type of Input | Note |
WDT | WDT | Resets Watch Dog Timer While Operating Program. |
WDTP | WDTP | Resets Watch Dog Timer While Operating Program. |
Carry
Instruction | Type of Input | Note |
STC | STC | If Input Condition Is On, Sets Carry Flag. |
CLC | CLC | If Input Condition Is ON, Resets Carry Flag. |
Refresh
Instruction | Type of Input | Note |
RFS | RFS (S) (n) | Refreshes n Pieces Of Device Which Are Assigned To S For One Scan. |
RFSP | RFSP (S) (n) | Refreshes n Pieces Of Device Which Are Assigned To S For One Scan. |
PID
Instruction | Type of Input | Note |
PIDCAL | PIDCAL (S) | Assigns Device Where Result Value Of PID Operation IS Stored As S. |
PIDINIT | PIDINIT (S) | Assigns Device Where The Set Value For PID Operation Is Stored As S. |
Trigonometric (XP Series)
Instruction | Type of Input | Note |
SIN | SIN (S) (D) | Calculates SIN (sine) value of angle designated at S and stores the operation result in the device number designated at D. |
COS | COS (S) (D) | Performs COS (cosine) on angle designated by S and stores operation result at device number designated by D . |
TAN | TAN (S) (D) | Performs tangent (TAN) operation on angle data designated by S , and stores operation result in device designated by D. |
ASIN | ASIN (S) (D) | Calculates angle from sin value designated by S, and stores operation result at word device designated by D |
ACOS | ACOS (S) (D) | Calculates angle from COS value designated by S, and stores operation result at word device designated by D |
ATAN | ATAN (S) (D) | Calculates angle from tan value designated by S, and stores operation result at word device desig |
BSIN | BSIN (S) (D) | Calculates the sin value of the designated value, and stores the sign of the operation result in the device at D, and the operation result in the device designated at D+1 and D+2. |
BCOS | BCOS (S) (D) | Calculates the cos value of the designated value, and stores the sign of the operation result in the device at D, and the operation result in the device designated at D+1 and D+2. |
BTAN | BTAN (S) (D) | Calculates TAN (tangent) value for value (angle) designated by S , and stores the sign for the operation result in the word device designated by D , and the operation result in the word device designated by D +1 and D +2. |
BASIN | BASIN (S) (D) | Calculates angle from sin value designated by S, and stores operation result at word device designated by D |
BACOS | BACOS (S) (D) | Calculates angle from COS value designated by S, and stores operation result at word device designated by D |
BATAN | BATAN (S) (D) | Calculates angle from sin value designated by S, and stores operation result at word device designated by D |
Exponent, Logarithm (XP Series)
Instruction | Type of Input | Note |
SQR | SQR (S) (D) | Calculates square root of value designated at S , and stores the operation result in the device number designated at D . |
EXP | EXP (S) (D) | Calculates exponent for value designated by S, and stores the result of the operation at the device designate by D |
LOG | LOG (S) (D) | Calculates natural logarithm of value designated by S taking e as base, and stores operation results at device designated by D. |
BSQR | BSQR (S) (D) | Store appointed data to area that is specified by D after square root arithmetic by S. |
BDSQR | BDSQR (S) (D) | Store appointed data to area that is specified by D after square root arithmetic by S. |
User Clock
Instruction | Type of Input | Note |
DUTY | DUTY (n1) (n2) (D) | Turns scan designated by n1 ON for user timing block designated by D, and scan designated by n2 OFF. |
Table
Instruction | Type of Input | Note |
FPOP | FPOP (DEV) (TBL) | Find Last Data In Table |
FINS | FINS (DEV) (TBL) (n) | Insert a Data In Table |
FDEL | FDEL (DEV) (TBL) (n) | Delete a Data From Table |
FIFR | FIFR (DEV) (TBL) | Read the oldest data from [TBL+1] and stores it at the device designated by [DEV]. After the execution of FIFR, the data in the table moves to the previous device and the last data will be zero. The number of data of the data table will be decreased. |
FIFRP | FIFRP (DEV) (TBL) | Read the oldest data from [TBL+1] and stores it at the device designated by [DEV]. After the execution of FIFR, the data in the table moves to the previous device and the last data will be zero. The number of data of the data table will be decreased. |
FIFW | FIFW (DEV) (TBL) | Stores the 16 bit data designated by [DEV] at the end of the data table designated by [TBL]. The number of data blocks stored at [TBL] will be increased. |
FIFWP | FIFWP (DEV) (TBL) | Stores the 16 bit data designated by [DEV] at the end of the data table designated by [TBL]. The number of data blocks stored at [TBL] will be increased. |
Redundant System
Instruction | Type of Input | Note |
ATVP | ATVP | Swap Active Status in Redundant System |
Scan program Enable / Disable
Instruction | Type of Input | Note |
EPGM | EPGM (n) | Permit driving of scan program that correspond to ID that is established by n. Change relevant scan program to Enable status in Disable status by DPGM command. if Disable Program command is not inputed at Mode conversion, it is all Enable PBT states |
DPGM | DPGM (n) | Permit driving of scan program that correspond to ID that is established by n. Change relevant scan program to Enable status in Disable status by DPGM command. if Disable Program command is not inputed at Mode conversion, it is all Enable PBT states |
Occur random number
Instruction | Type of Input | Note |
RND | RND (D) | Generates random number of from 0 to 32767, and stores at device designated by D |
SRND | SRND (D) | Updates random number series according to the 16-bit BIN data being stored in device designated by S. |
Scale
Instruction | Type of Input | Note |
SCL | SCL (S) (D) (P) (n) | Converts signed binary data into signed binary data according to Scale parameter table . |
SCLP | SCLP (S) (D) (P) (n) | Converts signed binary data into signed binary data according to Scale parameter table . |
Position (CP, XP)
Instruction | Type of Input | Note |
ABRST1 | ABRST1 (Base/Slot) (S) (D) |
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ABRST2 | ABRST2 (Base/Slot) (S) (D) |
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ABRST3 | ABRST3 (Base/Slot) (S) (D) |
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ABRST4 | ABRST4 (Base/Slot) (S) (D) |
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PSTRT1 | PSTRT1 (Base/Slot) (S) (D) |
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PSTRT2 | PSTRT2 (Base/Slot) (S) (D) |
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PSTRT3 | PSTRT3 (Base/Slot) (S) (D) |
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PSTRT4 | PSTRT4 (Base/Slot) (S) (D) |
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TEACH1 | TEACH1 (Base/Slot) (S) (D) |
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TEACH2 | TEACH2 (Base/Slot) (S) (D) |
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TEACH3 | TEACH3 (Base/Slot) (S) (D) |
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TEACH4 | TEACH4 (Base/Slot) (S) (D) |
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PFWRT | PFWRT (Base/Slot) (S) (D) |
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PINT | PINT (Base/Slot) (S) (D) |
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etc
Instruction | Type of Input | Note |
; | ; (notes) | Shows Description. |
DESCI | DESCI (notes) | Shows Description. |
NOP | NOP | As No Operation Instruction, Does Not Influence Operation Result Of The Corresponding Circuit. |