Comprehensive Guide to Mitsubishi PLC Instructions: Master All Series in One Place

Comprehensive Guide to Mitsubishi PLC Instructions: Master All Series in One Place

In the field of industrial automation, Mitsubishi PLCs (Programmable Logic Controllers) are widely adopted for their robust functionality and high reliability. This article provides a detailed breakdown of key Mitsubishi PLC instructions, including:

• Load and Output Instructions

• Contact Series and Parallel Connection Instructions

• Block Operation Instructions

• Set and Reset Instructions

• Pulse Differential Instructions

• Master Control Instructions

• Stack Instructions

• Invert/No Operation/End Instructions

• Step Ladder Instructions

Enabling comprehensive mastery of Mitsubishi PLC programming.

I. Load and Output Instructions

• LD (Load Instruction): Connects a normally open (NO) contact to the left power rail. Mandatory for logic lines starting with an NO contact.

• LDI (Load Inverse Instruction): Connects a normally closed (NC) contact to the left power rail. Mandatory for logic lines starting with an NC contact.

• LDP (Load Rising Edge Instruction): Detects the OFF→ON transition of an NO contact connected to the left power rail (activates for one scan cycle).

• LDF (Load Falling Edge Instruction): Detects the ON→OFF transition of an NC contact connected to the left power rail.

• OUT (Output Instruction): Drives a coil (output element).

Usage Notes:

• LD/LDI can connect to the left power rail or combine with ANB/ORB for block logic operations.

• LDP/LDF maintain activation for one scan cycle only upon valid edge detection.

• Target elements for LD/LDI/LDP/LDF: X, Y, M, T, C, S.

• OUT can be used consecutively (equivalent to parallel coils). For timers (T) and counters (C), specify constant K or a data register after OUT.

• Target elements for OUT: Y, M, T, C, S (not X).

II. Contact Series Connection Instructions

• AND: Series-connects an NO contact (logical AND).

• ANI (AND Inverse): Series-connects an NC contact (logical AND-NOT).

• ANDP: Rising-edge detection series connection.

• ANDF: Falling-edge detection series connection.

Usage Notes:

• AND/ANI/ANDP/ANDF support unlimited consecutive series connections.

• Target elements: X, Y, M, T, C, S.

• Example: OUT M101 followed by AND T1 driving Y4 is a "continuous output."

III. Contact Parallel Connection Instructions

• OR: Parallel-connects an NO contact (logical OR).

• ORI (OR Inverse): Parallel-connects an NC contact (logical OR-NOT).

• ORP: Rising-edge detection parallel connection.

• ORF: Falling-edge detection parallel connection.

Usage Notes:

• Left ends connect to LD/LDI/LDP/LPF; right ends link to the previous instruction’s right end. Unlimited parallel uses.

• Target elements: X, Y, M, T, C, S.

IV. Block Operation Instructions

• ORB (OR Block): Parallel connection of two or more series contact circuits.

• ANB (AND Block): Series connection of two or more parallel contact circuits.

Usage Notes:

• Each series circuit block in ORB must start with LD/LDI.

• Each parallel circuit block in ANB must start with LD/LDI.

• Limit of 8 consecutive ORB/ANB instructions.

V. Set and Reset Instructions

• SET: Activates and latches the target element.

• RST: Deactivates and clears the target element.

Usage Notes:

• SET targets: Y, M, S.

• RST targets: Y, M, S, T, C, D, V, Z. Clears data registers (D,Z,V) and resets latched timers/counters.

• Last-executed SET/RST for a given element takes precedence.

VI. Pulse Differential Instructions

• PLS (Pulse Rising Edge): Generates one scan-cycle pulse on OFF→ON transition.

• PLF (Pulse Falling Edge): Generates one scan-cycle pulse on ON→OFF transition.

Usage Notes:

• Targets: Y, M.

• PLS: Active for one scan cycle after driving input turns ON.

• PLF: Active for one scan cycle after driving input turns OFF.

VII. Master Control Instructions

• MC (Master Control): Connects common series contacts. Shifts the left power rail position.

• MCR (Master Control Reset): Resets MC, restoring the original left power rail.

Usage Notes:

• Targets: Y, M (not special relays).

• MC requires 3 program steps; MCR requires 2.

• The master control contact is a vertical NO contact connected to the left power rail. Contacts below it must start with LD/LDI.

• When MC input is OFF: Latched timers/counters and SET/RST-driven elements retain state; non-latched timers/counters and OUT-driven elements reset.

• Supports 8-level nesting (N0–N7). Reset with MCR in reverse order.

VIII. Stack Instructions

• MPS (Push Stack): Stores operation result to stack top.

• MRD (Read Stack): Reads top value without removal.

• MPP (Pop Stack): Reads top value and removes it.

Usage Notes:

• Target elements: None (stack only).

• MPS and MPP must be paired.

• Maximum stack depth: 11 levels.

IX. Invert, No Operation & End Instructions

• INV (Invert): Inverts the preceding logic result. Cannot connect to power rail or standalone.

• NOP (No Operation): Empty instruction (occupies one step). Used for temporary deletions.

• END (End): Terminates program execution. Reduces scan cycle time.

Usage Notes:

• Use END during debugging to isolate program sections.

X. Step Ladder Instructions

• STL (Step Ladder Contact): Activates step control with state relay S (e.g., STL S200).

• RET (Return): Exits step ladder and returns to main program.

State Transition Diagram:

• Sequential processes divide into states (steps), each performing unique actions.

• Transition occurs when conditions (e.g., X1=ON) are met.

• Each state defines:

• Output actions

• Transition condition

• Next-state target (e.g., S20 → S21).