Bộ điều khiển lập trình (PLC) IDEC dòng FC4A, FC5A được thay bằng PLC FC6A. Hoạt động nhằm nâng cao chất lượng sản phẩm,sự an toàn,thân thiện với người dùng
This document discusses system organization and input/output device interfaces. It covers several topics:
1. Single bus architecture with memory-mapped I/O and interface circuits to connect devices to the bus.
2. Program-controlled I/O using polling and interrupts to handle asynchronous devices.
3. Direct memory access (DMA) for high-speed transfer of blocks of data between memory and I/O devices.
4. Details of interrupt handling including priorities, nesting, and vectored interrupts.
This document provides an overview of the FP-X PLC system from Panasonic, including its control units, expansion units, add-on cassettes, and FP0 expansion units. The FP-X control units offer high-speed processing, large program capacity, and expandability. Expansion is enabled through add-on cassettes that add functions and I/O, and through FP0 expansion units that connect via an adapter and support a wide range of specialized I/O types. The FP-X is designed to meet a variety of automation requirements with flexible configuration options.
The document discusses important show commands for Cisco routers and switches. It provides a cheat sheet of the most useful show commands including show running-config, show version, show ip route, show interfaces, show cdp neighbors, and show clock. Each command is briefly described in terms of the key information it displays about the device, interfaces, configurations, or network.
The MELSEC FX2N Series has powerful CPUs and combines the advantages of compact PLCs and modular PLC systems. It has one of the fastest program cycle periods of just 0.08 μs per instruction. The base units have integrated inputs/outputs, power supply, CPU, and memory. They are available with 16 to 128 I/O points and different power supply options. Expansion units can add additional I/O points and special function modules provide additional functionality.
1. The document is a user manual for the DC4xD MK3 genset controller.
2. It provides instructions and specifications for the controller, including display features, protection functions, parameter options, installation guidelines, and wiring diagrams.
3. The controller is available in multiple models and is designed to monitor and control generators with options for remote control and communication.
1. The document describes how to connect a Cimrex terminal to a SIMATIC S7 PLC system via Profibus DP using the SIMATIC S7 Profibus DP driver.
2. Key steps include installing the driver in CIMREX PROG, configuring the communication settings, connecting the terminal to the Profibus DP network, and programming the PLC to support the HMI profile for data exchange.
3. The PLC program uses function blocks like FB110 to handle the HMI profile as well as data blocks for input/output areas and flags. The main program OB1 calls the function blocks to manage communication.
The document provides an overview of the MC9S08MP16 8-bit microcontroller that is well-suited for brushless DC motor control applications. It describes the microcontroller's features such as a 50MHz CPU, timers, analog comparators, ADC, and debug interface. Example applications discussed include industrial equipment, appliances, and medical devices. The document also outlines the microcontroller's block diagram, modes of operation, and the available evaluation board for development.
The document introduces Mitsubishi Electric's FX 3 series as the third generation of compact PLCs, noting their ease of use, flexibility, and affordability. It provides details on the FX3G, FX3U, and FX3UC models and their specifications, functionality for communication, networking, analog control, and positioning. Environmental specifications are also listed.
This document discusses system organization and input/output device interfaces. It covers several topics:
1. Single bus architecture with memory-mapped I/O and interface circuits to connect devices to the bus.
2. Program-controlled I/O using polling and interrupts to handle asynchronous devices.
3. Direct memory access (DMA) for high-speed transfer of blocks of data between memory and I/O devices.
4. Details of interrupt handling including priorities, nesting, and vectored interrupts.
This document provides an overview of the FP-X PLC system from Panasonic, including its control units, expansion units, add-on cassettes, and FP0 expansion units. The FP-X control units offer high-speed processing, large program capacity, and expandability. Expansion is enabled through add-on cassettes that add functions and I/O, and through FP0 expansion units that connect via an adapter and support a wide range of specialized I/O types. The FP-X is designed to meet a variety of automation requirements with flexible configuration options.
The document discusses important show commands for Cisco routers and switches. It provides a cheat sheet of the most useful show commands including show running-config, show version, show ip route, show interfaces, show cdp neighbors, and show clock. Each command is briefly described in terms of the key information it displays about the device, interfaces, configurations, or network.
The MELSEC FX2N Series has powerful CPUs and combines the advantages of compact PLCs and modular PLC systems. It has one of the fastest program cycle periods of just 0.08 μs per instruction. The base units have integrated inputs/outputs, power supply, CPU, and memory. They are available with 16 to 128 I/O points and different power supply options. Expansion units can add additional I/O points and special function modules provide additional functionality.
1. The document is a user manual for the DC4xD MK3 genset controller.
2. It provides instructions and specifications for the controller, including display features, protection functions, parameter options, installation guidelines, and wiring diagrams.
3. The controller is available in multiple models and is designed to monitor and control generators with options for remote control and communication.
1. The document describes how to connect a Cimrex terminal to a SIMATIC S7 PLC system via Profibus DP using the SIMATIC S7 Profibus DP driver.
2. Key steps include installing the driver in CIMREX PROG, configuring the communication settings, connecting the terminal to the Profibus DP network, and programming the PLC to support the HMI profile for data exchange.
3. The PLC program uses function blocks like FB110 to handle the HMI profile as well as data blocks for input/output areas and flags. The main program OB1 calls the function blocks to manage communication.
The document provides an overview of the MC9S08MP16 8-bit microcontroller that is well-suited for brushless DC motor control applications. It describes the microcontroller's features such as a 50MHz CPU, timers, analog comparators, ADC, and debug interface. Example applications discussed include industrial equipment, appliances, and medical devices. The document also outlines the microcontroller's block diagram, modes of operation, and the available evaluation board for development.
The document introduces Mitsubishi Electric's FX 3 series as the third generation of compact PLCs, noting their ease of use, flexibility, and affordability. It provides details on the FX3G, FX3U, and FX3UC models and their specifications, functionality for communication, networking, analog control, and positioning. Environmental specifications are also listed.
The document provides information on Mitsubishi Programmable Controllers Series 10, including its lineup of CPUs, modules, software, solutions, specifications, and support. The Series 10 offers a range of CPU options from basic to high-performance models for sequence, motion, process, and information control applications. It allows integrating four automation control types onto a single system.
The document provides specifications for Mitsubishi's new FX3GE programmable logic controller (PLC) series. The FX3GE series features built-in analog input/output and Ethernet connectivity in addition to the standard functionality of the FX3G series. It can be used for a variety of automation applications, such as flow control in the food industry. The FX3GE series offers expandability through expansion boards, communication adapters, and analog adapters. It provides flexible and cost-effective control with built-in analog and network functions for applications such as production monitoring over Ethernet.
The document describes a stepper motor controller circuit and program that can control the number of rotations, direction, and speed of a stepper motor using a PC's parallel port.
The circuit uses optocouplers to interface the parallel port data lines to a ULN2003 driver chip. This drives a 4-lead stepper motor. A C program controls the motor by sending pulse sequences to the parallel port to rotate it clockwise or counterclockwise. User input determines the number of rotations, direction, and speed. Pulse timing is varied to control motor speed.
The document provides a test with 100% questions from chapters 1-11 of the CCNA 2 curriculum. It tests knowledge of router components, configuration, interfaces, protocols and standards used in networking. The questions cover topics such as router memory, management connections, terminal emulation settings, functions of RAM, flash memory and NVRAM, router startup processes, console port cabling, interface modes and commands.
This document provides information on various ROBO Cylinder controllers including:
1) It categorizes the controllers into three groups: positioner type, program type, and network type based on their operations and functions.
2) It provides tables that list the controller models and corresponding positioner/actuator types as well as specifications like input voltage, number of controllable axes, and supported field networks.
3) It includes sections that provide overviews of the different controller types including 3-position controllers, program controllers, and network compatible controllers.
JVL Process Control Modules for JVL MAC Motors Electromate
The MAC00-P4 and MAC00-P5 are expansion modules that provide analog and digital I/O for JVL MAC motors from 400 to 3000. They feature a 4-20mA analog input and output, status outputs, and interfaces for connecting a secondary "slave" motor. The modules also include power supply inputs and outputs, isolated communication interfaces, and connectors for basic I/O, power, communication, and connecting a slave motor.
This document provides instructions for restoring an APC device's SPI EEPROM using an external programmer like the FlashcatUSB. It involves:
1. Preparing the FlashcatUSB programmer and downloading necessary files from APC and Microsoft websites.
2. Connecting the FlashcatUSB to the APC and running FlashcatUSB software to write the firmware BIN file to the APC's SPI EEPROM.
3. Reinstalling the system firmware from a microSD card and resetting the LAN MAC address using a console cable connected to the APC's debug port.
8259 A P R O G R A M M A B L E I N T E R R U P T C O N T R O L L E R2Aisu
The 8259A Programmable Interrupt Controller (PIC) is used to handle multiple interrupt requests from I/O devices connected to CPUs. It can manage up to 8 interrupt requests with different priority levels. It consists of registers and logic circuits that prioritize interrupts and direct the CPU to the correct interrupt handling routine. It allows flexible and expandable interrupt management for systems with numerous I/O devices generating interrupts.
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Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
Điện Công Nghiệp Mitsubishi, Điện Công Nghiệp,
Điện Hạ Thế Mitsubishi, Điện Hạ Thế,
Điện Dân Dụng Mitsubishi, Điện Dân Dụng,
Mitsubishi,
Thiết Bị Đóng Cắt Mitsubishi, Thiết Bị Đóng Cắt,
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
The 8259 Programmable Interrupt Controller (PIC) is used to expand the number of interrupts for processors like the 8085. It can manage up to 8 interrupt requests at once and allow them to be serviced one by one. The 8259 can be programmed to determine interrupt priorities and masking. It is interfaced with the 8085 through I/O mapping and provides the interrupt acknowledge response by outputting the call opcode and address.
The document summarizes Mitsubishi Electric's new FX1S and FX1N series of programmable logic controllers (PLCs). The new PLCs have improved basic performance with faster processing speeds, more memory, and higher counter frequencies. They also have enhanced positioning functions with faster pulse outputs and new commands. A variety of display modules are available, including add-on and panel-mounted types with multiple languages and setup functions. The PLCs also have improved communication functions allowing larger networks of up to 16 units. They maintain compatibility with previous Mitsubishi PLC models for easy upgrades.
The document provides information about the Intel 8255 Programmable Peripheral Interface chip. It includes a block diagram and descriptions of the main components. The 8255 has 3 8-bit ports (A, B, C) that can be configured in different operating modes for input/output. It describes the pin functions and how the 8255 can interface with the Intel 8085 microprocessor. The main operating modes - I/O, bit set/reset, and the various configurations for ports A, B and C in each mode - are summarized.
The expansion module MAC00-FP4 allows MAC motors to connect to a Profibus DP network. It acts as a Profibus DP slave and allows reading and writing of all motor registers through Profibus. The module has 6 isolated digital inputs and 2 isolated digital outputs. It connects to the motor with M12 connectors and to the Profibus network with M12 connectors for easy installation in harsh environments. Sample Profibus configuration files and PLC code are provided for quick setup.
This document contains 20 multiple choice questions and answers from the CCNA 2 Chapter 7 exam on RIP routing. The questions cover topics like RIP version 1 and 2 configuration, using the network command, and troubleshooting RIP issues.
This study guide is intended to provide those pursuing the CCNA certification with a framework of what concepts need to be studied. This is not a comprehensive document containing all the secrets of the CCNP nor is it a “braindump” of questions and answers.
I sincerely hope that this document provides some assistance and clarity in your studies.
The document contains questions and answers related to CCNA 2 Chapter 5 routing protocols. The high-level information provided is:
1) The document contains practice questions and answers for the CCNA 2 Chapter 5 exam on routing protocols.
2) The questions cover topics such as RIP configuration, route summarization, default routes, and examining routing tables.
3) Answering the questions involves interpreting routing protocol output and configuration to determine routing behavior.
The document provides an overview of the key features and architecture of NXP Semiconductors' LPC213x microcontroller family. The LPC213x MCUs are based on an ARM7TDMI-S CPU with on-chip flash memory and RAM. They include features such as GPIO ports, UARTs, I2C interfaces, SPI, PWM, ADC, DAC, RTC, and watchdog timer. The MCUs also support in-system programming, debugging via EmbeddedICE, and instruction tracing with an embedded trace macrocell.
The document describes the ROBO Cylinder ERC3 series, which comprises a built-in controller and actuator. Key features of the ERC3 include being space-saving due to not requiring a separate controller, allowing for teaching close to the actuator, and having an increased maximum payload, speed, and stroke compared to conventional models. The ERC3 comes in various types and models for different applications. It can be operated using a built-in controller, teaching pendant, software, or Quick Teach accessory without needing a PLC or power supply in some cases.
The 8259 Programmable Interrupt Controller (PIC) handles multiple interrupt requests from I/O devices connected to the CPU. It has 8 interrupt lines and can prioritize and process interrupts. It includes registers to store interrupt requests and service status, and can cascade with other PICs to handle more interrupts. When an interrupt occurs, the PIC sends a call instruction to the CPU, then the interrupt service routine address, allowing the CPU to service high-priority interrupts first in a multitasking system.
This document provides details about the MSP430x5xx microcontroller including its block diagram, CPU architecture, memory map, I/O ports, interrupts, clock system, low power modes, watchdog timer and more. Key aspects include its 16-bit RISC CPU, various clock signals, flash memory up to 512KB, RAM up to 66KB, 8 I/O ports, analog to digital converter, timers, real-time clock, and low power modes down to 0.1uA. Example code is provided to configure ports for output and LED interfacing.
The document provides information about upgrading generator controls from a PowerCommand PCC 3100 or Detector control system to a PowerCommand 3.3 control system. It lists the parts and kits needed for the upgrade based on the original control, engine/alternator type, and accessories. Key information includes upgrade kits for PCC 3100 paralleling or basic controls, Detector controls, optional accessory kits, additional PowerCommand accessory kits, and current transformer kits.
The document provides information on Mitsubishi Programmable Controllers Series 10, including its lineup of CPUs, modules, software, solutions, specifications, and support. The Series 10 offers a range of CPU options from basic to high-performance models for sequence, motion, process, and information control applications. It allows integrating four automation control types onto a single system.
The document provides specifications for Mitsubishi's new FX3GE programmable logic controller (PLC) series. The FX3GE series features built-in analog input/output and Ethernet connectivity in addition to the standard functionality of the FX3G series. It can be used for a variety of automation applications, such as flow control in the food industry. The FX3GE series offers expandability through expansion boards, communication adapters, and analog adapters. It provides flexible and cost-effective control with built-in analog and network functions for applications such as production monitoring over Ethernet.
The document describes a stepper motor controller circuit and program that can control the number of rotations, direction, and speed of a stepper motor using a PC's parallel port.
The circuit uses optocouplers to interface the parallel port data lines to a ULN2003 driver chip. This drives a 4-lead stepper motor. A C program controls the motor by sending pulse sequences to the parallel port to rotate it clockwise or counterclockwise. User input determines the number of rotations, direction, and speed. Pulse timing is varied to control motor speed.
The document provides a test with 100% questions from chapters 1-11 of the CCNA 2 curriculum. It tests knowledge of router components, configuration, interfaces, protocols and standards used in networking. The questions cover topics such as router memory, management connections, terminal emulation settings, functions of RAM, flash memory and NVRAM, router startup processes, console port cabling, interface modes and commands.
This document provides information on various ROBO Cylinder controllers including:
1) It categorizes the controllers into three groups: positioner type, program type, and network type based on their operations and functions.
2) It provides tables that list the controller models and corresponding positioner/actuator types as well as specifications like input voltage, number of controllable axes, and supported field networks.
3) It includes sections that provide overviews of the different controller types including 3-position controllers, program controllers, and network compatible controllers.
JVL Process Control Modules for JVL MAC Motors Electromate
The MAC00-P4 and MAC00-P5 are expansion modules that provide analog and digital I/O for JVL MAC motors from 400 to 3000. They feature a 4-20mA analog input and output, status outputs, and interfaces for connecting a secondary "slave" motor. The modules also include power supply inputs and outputs, isolated communication interfaces, and connectors for basic I/O, power, communication, and connecting a slave motor.
This document provides instructions for restoring an APC device's SPI EEPROM using an external programmer like the FlashcatUSB. It involves:
1. Preparing the FlashcatUSB programmer and downloading necessary files from APC and Microsoft websites.
2. Connecting the FlashcatUSB to the APC and running FlashcatUSB software to write the firmware BIN file to the APC's SPI EEPROM.
3. Reinstalling the system firmware from a microSD card and resetting the LAN MAC address using a console cable connected to the APC's debug port.
8259 A P R O G R A M M A B L E I N T E R R U P T C O N T R O L L E R2Aisu
The 8259A Programmable Interrupt Controller (PIC) is used to handle multiple interrupt requests from I/O devices connected to CPUs. It can manage up to 8 interrupt requests with different priority levels. It consists of registers and logic circuits that prioritize interrupts and direct the CPU to the correct interrupt handling routine. It allows flexible and expandable interrupt management for systems with numerous I/O devices generating interrupts.
Mitsubishi plc fxfamilycatalogverf-160517025323 dienhathe.vnDien Ha The
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
Điện Công Nghiệp Mitsubishi, Điện Công Nghiệp,
Điện Hạ Thế Mitsubishi, Điện Hạ Thế,
Điện Dân Dụng Mitsubishi, Điện Dân Dụng,
Mitsubishi,
Thiết Bị Đóng Cắt Mitsubishi, Thiết Bị Đóng Cắt,
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
The 8259 Programmable Interrupt Controller (PIC) is used to expand the number of interrupts for processors like the 8085. It can manage up to 8 interrupt requests at once and allow them to be serviced one by one. The 8259 can be programmed to determine interrupt priorities and masking. It is interfaced with the 8085 through I/O mapping and provides the interrupt acknowledge response by outputting the call opcode and address.
The document summarizes Mitsubishi Electric's new FX1S and FX1N series of programmable logic controllers (PLCs). The new PLCs have improved basic performance with faster processing speeds, more memory, and higher counter frequencies. They also have enhanced positioning functions with faster pulse outputs and new commands. A variety of display modules are available, including add-on and panel-mounted types with multiple languages and setup functions. The PLCs also have improved communication functions allowing larger networks of up to 16 units. They maintain compatibility with previous Mitsubishi PLC models for easy upgrades.
The document provides information about the Intel 8255 Programmable Peripheral Interface chip. It includes a block diagram and descriptions of the main components. The 8255 has 3 8-bit ports (A, B, C) that can be configured in different operating modes for input/output. It describes the pin functions and how the 8255 can interface with the Intel 8085 microprocessor. The main operating modes - I/O, bit set/reset, and the various configurations for ports A, B and C in each mode - are summarized.
The expansion module MAC00-FP4 allows MAC motors to connect to a Profibus DP network. It acts as a Profibus DP slave and allows reading and writing of all motor registers through Profibus. The module has 6 isolated digital inputs and 2 isolated digital outputs. It connects to the motor with M12 connectors and to the Profibus network with M12 connectors for easy installation in harsh environments. Sample Profibus configuration files and PLC code are provided for quick setup.
This document contains 20 multiple choice questions and answers from the CCNA 2 Chapter 7 exam on RIP routing. The questions cover topics like RIP version 1 and 2 configuration, using the network command, and troubleshooting RIP issues.
This study guide is intended to provide those pursuing the CCNA certification with a framework of what concepts need to be studied. This is not a comprehensive document containing all the secrets of the CCNP nor is it a “braindump” of questions and answers.
I sincerely hope that this document provides some assistance and clarity in your studies.
The document contains questions and answers related to CCNA 2 Chapter 5 routing protocols. The high-level information provided is:
1) The document contains practice questions and answers for the CCNA 2 Chapter 5 exam on routing protocols.
2) The questions cover topics such as RIP configuration, route summarization, default routes, and examining routing tables.
3) Answering the questions involves interpreting routing protocol output and configuration to determine routing behavior.
The document provides an overview of the key features and architecture of NXP Semiconductors' LPC213x microcontroller family. The LPC213x MCUs are based on an ARM7TDMI-S CPU with on-chip flash memory and RAM. They include features such as GPIO ports, UARTs, I2C interfaces, SPI, PWM, ADC, DAC, RTC, and watchdog timer. The MCUs also support in-system programming, debugging via EmbeddedICE, and instruction tracing with an embedded trace macrocell.
The document describes the ROBO Cylinder ERC3 series, which comprises a built-in controller and actuator. Key features of the ERC3 include being space-saving due to not requiring a separate controller, allowing for teaching close to the actuator, and having an increased maximum payload, speed, and stroke compared to conventional models. The ERC3 comes in various types and models for different applications. It can be operated using a built-in controller, teaching pendant, software, or Quick Teach accessory without needing a PLC or power supply in some cases.
The 8259 Programmable Interrupt Controller (PIC) handles multiple interrupt requests from I/O devices connected to the CPU. It has 8 interrupt lines and can prioritize and process interrupts. It includes registers to store interrupt requests and service status, and can cascade with other PICs to handle more interrupts. When an interrupt occurs, the PIC sends a call instruction to the CPU, then the interrupt service routine address, allowing the CPU to service high-priority interrupts first in a multitasking system.
This document provides details about the MSP430x5xx microcontroller including its block diagram, CPU architecture, memory map, I/O ports, interrupts, clock system, low power modes, watchdog timer and more. Key aspects include its 16-bit RISC CPU, various clock signals, flash memory up to 512KB, RAM up to 66KB, 8 I/O ports, analog to digital converter, timers, real-time clock, and low power modes down to 0.1uA. Example code is provided to configure ports for output and LED interfacing.
The document provides information about upgrading generator controls from a PowerCommand PCC 3100 or Detector control system to a PowerCommand 3.3 control system. It lists the parts and kits needed for the upgrade based on the original control, engine/alternator type, and accessories. Key information includes upgrade kits for PCC 3100 paralleling or basic controls, Detector controls, optional accessory kits, additional PowerCommand accessory kits, and current transformer kits.
The P89V51RD2 is an 80C51 microcontroller with 64kB of Flash memory and 1kB of RAM. It has features like In-System Programming, In-Application Programming, and a choice of running at the standard 80C51 clock rate or twice the throughput at the same clock frequency in X2 mode. It includes ports, timers, serial interfaces, and low power modes.
The document provides an overview of the Silicon Labs C8051F020 microcontroller. It describes the microcontroller's CPU, memory organization, I/O ports, analog and digital peripherals such as ADCs, DACs, and comparators. It also discusses the microcontroller's special function registers used to control and interface with its various peripherals.
The document provides details about the 8086 microprocessor architecture. Some key points:
- The 8086 is a 16-bit microprocessor that can access up to 1MB of memory using a 20-bit address bus and supports up to 64K I/O ports.
- It has an internal architecture divided into a Bus Interface Unit (BIU) and Execution Unit (EU) that allows for overlapping of instruction fetching and execution via pipelining.
- The BIU handles external bus operations like instruction fetching and memory/I/O access. The EU decodes and executes instructions, performing operations on operands retrieved by the BIU.
This document describes an analog input/output option board. It includes sections that cover:
- General specifications of the board
- Installation and setting procedures, including memory allocation
- Details on the analog input, output, and I/O option boards including specifications, terminal arrangements, and wiring
- Usage examples and troubleshooting tips
Program, Code of Program and Screen Shot of Output (UNIVERSAL DRIVER USING µ...Er. Ashish Pandey
The document describes a program for a universal motor driver using a P89C51 microcontroller. It can control AC and DC motors by varying the pulse width modulation (PWM) of the TRIAC for AC motors and switching relays for DC motor voltage levels. The program uses timers and interrupts to generate the PWM and reads inputs to control motor speed and select motor type/voltage. Screenshots show the operating scheme and motor control via keypad input to the serial port.
Best practices for catalyst 4500 4000, 5500-5000, and 6500-6000 series switch...abdenour boussioud
This document provides best practices for configuring Cisco Catalyst 4500/4000, 5500/5000, and 6500/6000 series switches running CatOS. It discusses protocols like CDP, DTP, STP, EtherChannel and VLAN Trunking Protocol that are used for switch-to-switch communication. It also covers management topics such as SNMP, syslog, NTP and security configurations using features like TACACS+. The document is divided into sections on basic configuration, management, security and a configuration checklist.
1. The X-SEL PX/QX controllers can control SCARA robots with up to 6 axes total, including the SCARA robot and additional single or cartesian axis robots.
2. The QX series are "global types" that conform to safety category 4 and require an external safety circuit, while the PX series have an internal safety circuit.
3. The controllers have functions like conveyor tracking using vision and high performance processing in a compact design that is CE compliant.
8259 programmable PPI interfacing with 8085 .pptDrVikasMahor
This document provides information about the 8259A Programmable Interrupt Controller chip. It describes the chip's features such as supporting 8 levels of priority and being expandable up to 64 levels. It also explains how the chip works as an interrupt manager in a system, accepting requests from peripherals and determining which has highest priority to issue to the CPU. Block diagrams and explanations of the chip's registers and pins are provided.
The document summarizes the Voice Internetworking Multiplexer (VIM) product from Marconi. The VIM extends ATM corporate networks to remote sites, enabling toll-quality voice and data integration over the same connection. It has 8 ATM telephony ports, a 155 Mbps ATM OC-3 connection, a T1/E1 WAN link, and a 10Base-T Ethernet port. The VIM provides a cost-effective way to consolidate networks and extend telephony services to remote locations with up to 192 total ports.
American Fibertek MTX46FXSTPOEPLUS Data SheetJMAC Supply
The 46-PoE+ Series is a media converter and 3-port switch that transmits and receives Ethernet signals over either singlemode or multimode fiber and copper connections. It provides Power over Ethernet (PoE) on both RJ45 ports, delivering up to 802.3af (15W) or 802.3at (30W) of power to powered devices. The unit automatically detects connection speed and type to simplify installation. Diagnostic indicators provide status information and the compact module size makes it suitable for field applications.
The document discusses control systems and their evolution. It provides an overview of analog control systems, digital control systems, centralized control systems, and distributed control systems. It then focuses on Yokogawa's CENTUM distributed control system (DCS), describing its components, configurations, and I/O modules.
The BranchHub provides telephone service to small branch offices by consolidating trunk and station media gateway functions into a single device. It connects 6 analog phone lines to the PSTN and 12 analog station ports for phones. The BranchHub guarantees continuous operation even during power or network failures by switching connected phones to the PSTN. It can connect to networks via ATM or Ethernet and is configured remotely from a Sphericall Manager.
How to design a Passive Infrared (PIR) Open Source ProjectIonela
This article details the hardware and software required for a fully functional passive infrared (PIR) sensor with an associated remote control unit. The remote control unit adjusts key algorithm detection parameters which are stored in the MC68HC908JK1/3 FLASH memory area.
The Z1000 variable speed drive is designed for building automation applications like fans, pumps and cooling towers up to 500 HP. It features an easy-to-use LCD interface and real-time clock for reliable motor control. The drive offers control methods like V/Hz and open loop vector control for various motor types in different enclosures up to 500 HP with standard I/O, communications and certifications for most building automation needs.
FREJA Win 6.2 is relay test equipment software that works with new FREJA 400 series test sets and is backwards compatible with FREJA 300 and 306 test sets. It requires a certain firmware version in FREJA 400 test sets. New features in FREJA Win 6.2 include installing in FREJA 400 or 300 mode, importing custom network models, starting offline for some FREJA 400 models, showing IP addresses of connected FREJA units, and improved error handling and communication speed. It also adds the ability to control solid state outputs and battery simulators, dynamically change instrument views, name sequencer states, and improve waveform and max time graphics.
Similar to IDEC thay thế PLC dòng FC4A, FC5A bằng dòng PLC mới FC6A (20)
Hạo Phương xin giới thiệu đến quý khách hàng cách cài đặt cơ bản dòng biến tần MD290. Biến tần Inovance MD290 là dòng sản phẩm đa năng rất dễ sử dụng và đem lại hiệu quả cho việc điều khiển tốc độ động cơ và các ứng dụng đặc biệt khác. Biến tần Inovance MD290 dùng cho các ứng dụng: điều khiển băng tải, bơm chân không kiểu piston, vận chuyển vật liệu, máy chế biến gỗ,…
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This document announces the discontinuation of several control unit products from IDEC Corporation. It provides details on products being discontinued, their recommended replacements, and last order and delivery dates. Key products being discontinued include LED illuminated white colored products, control units with 6V AC/DC illumination ratings, some emergency stop switches and selector switches, and other low selling items. Replacements or last order dates are provided for most discontinued products.
Những lưu ý khi sử dụng máy lọc nước tại vòi Cleansui CSP601CTY TNHH HẠO PHƯƠNG
Bạn vừa mới mua sản phẩm máy lọc nước tại vòi Cleansui CSP601, và lo lắng không biết sử dụng như thế nào đúng cách. Dưới đây là một số lưu ý mà chúng tôi đưa ra giúp bạn đảm bảo an toàn cũng như là đảm bảo nguồn nước sạch khi sử dụng sản phẩm.
Beeteco xin gửi đến quý khách bảng giá biến tần Inovance mới nhất 2020 bao gồm giá chi tiết của các dòng sản phẩm:
Biến tần Inovance MD200
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Công ty Cổ phần Hạo Phương xin gửi đến quý khách hàng catalog biến tần Inovance MD500. Catalog chứa đầy đủ thông tin về sản phẩm, kích thước và những lưu ý để sử dụng thiết bị hiệu quả.
Quý khách có nhu cầu mua hàng hoặc hợp tác cùng chúng tôi xin vui lòng liên hệ theo địa chỉ :
CÔNG TY CỔ PHẦN HẠO PHƯƠNG
Trụ sở chính:
Địa chỉ: Số 88 đường Vĩnh Phú 40, Kp. Hòa Long, P. Vĩnh Phú, Thuận An, Bình Dương.
Văn phòng Hà Nội:
Địa chỉ: Số 95 TT4 – KĐT Mỹ Đình Sông Đà – Phường Mỹ Đình – Q. Nam Từ Liêm – Hà Nội
Chi nhánh Cambodia:
Địa chỉ: The Park Land SenSok, Borey Chip Mong, House Number 22, P11.Sangkat Phnom Penh Thmey, Khan San Sok, Phnom Penh.
Email: cs@haophuong.com – Website: haophuong.com
Facebook: https://www.facebook.com/haophuongcompany/
HOTLINE: 1800 6547
The document is a user guide for the MD310 AC drive from Shenzhen Inovance Technology Co., Ltd. It provides information on product specifications, wiring, setup, troubleshooting, and parameters. The guide covers safety precautions, nameplate details, terminal descriptions, typical wiring diagrams, easy setup instructions, fault solutions, and tables of general and monitoring parameters.
Công ty Cổ phần Hạo Phương xin gửi đến quý khách hàng catalog biến tần Inovance MD290. Catalog chứa đầy đủ thông tin về sản phẩm, kích thước và những lưu ý để sử dụng thiết bị hiệu quả.
Quý khách có nhu cầu mua hàng hoặc hợp tác cùng chúng tôi xin vui lòng liên hệ theo địa chỉ :
CÔNG TY CỔ PHẦN HẠO PHƯƠNG
Trụ sở chính:
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Email: cs@haophuong.com – Website: haophuong.com
Facebook: https://www.facebook.com/haophuongcompany/
HOTLINE: 1800 6547
This document provides product information for MD200 AC drives, including:
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Beeteco xin gửi đến quý khách hàng Catalog biến tần Inovance dòng MD500 với đầy đủ thông tin về sản phẩm, kích thước, những lưu ý để sử dụng thiết bị hiệu quả.
Contact:
Trụ sở TP.HCM: Số 139-141 đường Phú Châu, Kp. 1, P. Tam Bình, Q. Thủ Đức, Tp. Hồ Chí Minh
Tel: (028) 3636 5671|2|3 - Fax: (028) 3636 5674
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Tel: (024) 320 11 408 | 320 11 410
Email: contact@beeteco.com - MST: 3702357207
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The document provides instructions for using an AC drive product from Inovance. It includes information about nameplate and model number, components, technical specifications, dimensions, system connections, installation, wiring, operation, maintenance and safety precautions. The document is the user guide for Inovance MD290 series AC drives for power ratings between 500-630 kW.
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Thông tin liên hệ:
Trụ sở TP.HCM: Số 139-141 đường Phú Châu, Kp. 1, P. Tam Bình, Q. Thủ Đức, Tp. Hồ Chí Minh
Tel: (028) 3636 5671|2|3 - Fax: (028) 3636 5674
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Tel: (024) 320 11 408 | 320 11 410
Email: contact@beeteco.com - MST: 3702357207
Beeteco gửi đến quý khách hàng catalog thiết bị điện của thương hiệu Vteke. Catalog chứa đầy đủ thông tin về sản phẩm, kích thước và những lưu ý để sử dụng thiết bị hiệu quả.
=========================================
Beeteco.com@ Công ty TNHH Thương Mại Kỹ Thuật ASTER
Hotline: 0909.41.61.43
Email: contact@beeteco.com
Fanpage: www.facebook.com/beeteco
Địa chỉ: 7/31 KDC Thương Mại Sóng Thần, KP. Nhị Đồng 1, P. Dĩ An, Tx. Dĩ An, Tỉnh Bình Dương.
Quý khách có nhu cầu mua hàng hoặc hợp tác cùng chúng tôi xin vui lòng liên hệ theo địa chỉ :
CÔNG TY CỔ PHẦN HẠO PHƯƠNG
Trụ sở chính:
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Văn phòng Hà Nội:
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Chi nhánh Cambodia:
Địa chỉ: The Park Land SenSok, Borey Chip Mong, House Number 22, P11.Sangkat Phnom Penh Thmey, Khan San Sok, Phnom Penh.
Email: cs@haophuong.com – Website: haophuong.com
Facebook: https://www.facebook.com/haophuongcompany/
HOTLINE: 1800 6547
Quý khách có nhu cầu mua hàng hoặc hợp tác cùng chúng tôi xin vui lòng liên hệ theo địa chỉ :
CÔNG TY CỔ PHẦN HẠO PHƯƠNG
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Địa chỉ: The Park Land SenSok, Borey Chip Mong, House Number 22, P11.Sangkat Phnom Penh Thmey, Khan San Sok, Phnom Penh.
Email: cs@haophuong.com – Website: haophuong.com
Facebook: https://www.facebook.com/haophuongcompany/
HOTLINE: 1800 6547
The document announces that several HG series operator interface products will be discontinued due to parts no longer being available from suppliers. It provides details on the specific products being discontinued, their recommended replacements, and the schedule including last order and delivery dates. Support for maintenance will be available until late 2026 depending on remaining stock. Customers are advised to place final orders by November 2019 to ensure supply of the discontinued products.
Màn hình cảm ứng dòng V9 là sản phẩm của nhà sản xuất Fuji Electric. Với khả năng giao tiếp mạnh mẽ, đáp ứng được yêu cầu trong tất cả các ngành công nghiệp.
HMI Fuji Electric dòng TS là sản phẩm có khả năng giao tiếp mạnh mẽ, TECHNOSHOT đáp ứng được yêu cầu trong tất cả các ngành công nghiệp. Sản phẩm có giao diện được lập trình một cách trực quan nhất, màn hình với độ sắc nét lên đến 64k màu. Tấm nền TFT cho độ sáng cao và có khả năng tái tạo màu tốt.
The BM3RSB- and BM3RHB- series are 32AF manual motor starters that provide adjustable thermal-magnetic trip protection for motors up to 15kW. They have standard breaking capacities of 25-100kA and compact dimensions. Accessories include auxiliary contact blocks, undervoltage trip devices, and enclosures.
Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapte...University of Maribor
Slides from talk presenting:
Aleš Zamuda: Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapter and Networking.
Presentation at IcETRAN 2024 session:
"Inter-Society Networking Panel GRSS/MTT-S/CIS
Panel Session: Promoting Connection and Cooperation"
IEEE Slovenia GRSS
IEEE Serbia and Montenegro MTT-S
IEEE Slovenia CIS
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3-6 June 2024, Niš, Serbia
DEEP LEARNING FOR SMART GRID INTRUSION DETECTION: A HYBRID CNN-LSTM-BASED MODELgerogepatton
As digital technology becomes more deeply embedded in power systems, protecting the communication
networks of Smart Grids (SG) has emerged as a critical concern. Distributed Network Protocol 3 (DNP3)
represents a multi-tiered application layer protocol extensively utilized in Supervisory Control and Data
Acquisition (SCADA)-based smart grids to facilitate real-time data gathering and control functionalities.
Robust Intrusion Detection Systems (IDS) are necessary for early threat detection and mitigation because
of the interconnection of these networks, which makes them vulnerable to a variety of cyberattacks. To
solve this issue, this paper develops a hybrid Deep Learning (DL) model specifically designed for intrusion
detection in smart grids. The proposed approach is a combination of the Convolutional Neural Network
(CNN) and the Long-Short-Term Memory algorithms (LSTM). We employed a recent intrusion detection
dataset (DNP3), which focuses on unauthorized commands and Denial of Service (DoS) cyberattacks, to
train and test our model. The results of our experiments show that our CNN-LSTM method is much better
at finding smart grid intrusions than other deep learning algorithms used for classification. In addition,
our proposed approach improves accuracy, precision, recall, and F1 score, achieving a high detection
accuracy rate of 99.50%.
A SYSTEMATIC RISK ASSESSMENT APPROACH FOR SECURING THE SMART IRRIGATION SYSTEMSIJNSA Journal
The smart irrigation system represents an innovative approach to optimize water usage in agricultural and landscaping practices. The integration of cutting-edge technologies, including sensors, actuators, and data analysis, empowers this system to provide accurate monitoring and control of irrigation processes by leveraging real-time environmental conditions. The main objective of a smart irrigation system is to optimize water efficiency, minimize expenses, and foster the adoption of sustainable water management methods. This paper conducts a systematic risk assessment by exploring the key components/assets and their functionalities in the smart irrigation system. The crucial role of sensors in gathering data on soil moisture, weather patterns, and plant well-being is emphasized in this system. These sensors enable intelligent decision-making in irrigation scheduling and water distribution, leading to enhanced water efficiency and sustainable water management practices. Actuators enable automated control of irrigation devices, ensuring precise and targeted water delivery to plants. Additionally, the paper addresses the potential threat and vulnerabilities associated with smart irrigation systems. It discusses limitations of the system, such as power constraints and computational capabilities, and calculates the potential security risks. The paper suggests possible risk treatment methods for effective secure system operation. In conclusion, the paper emphasizes the significant benefits of implementing smart irrigation systems, including improved water conservation, increased crop yield, and reduced environmental impact. Additionally, based on the security analysis conducted, the paper recommends the implementation of countermeasures and security approaches to address vulnerabilities and ensure the integrity and reliability of the system. By incorporating these measures, smart irrigation technology can revolutionize water management practices in agriculture, promoting sustainability, resource efficiency, and safeguarding against potential security threats.
We have compiled the most important slides from each speaker's presentation. This year’s compilation, available for free, captures the key insights and contributions shared during the DfMAy 2024 conference.
Using recycled concrete aggregates (RCA) for pavements is crucial to achieving sustainability. Implementing RCA for new pavement can minimize carbon footprint, conserve natural resources, reduce harmful emissions, and lower life cycle costs. Compared to natural aggregate (NA), RCA pavement has fewer comprehensive studies and sustainability assessments.
Embedded machine learning-based road conditions and driving behavior monitoringIJECEIAES
Car accident rates have increased in recent years, resulting in losses in human lives, properties, and other financial costs. An embedded machine learning-based system is developed to address this critical issue. The system can monitor road conditions, detect driving patterns, and identify aggressive driving behaviors. The system is based on neural networks trained on a comprehensive dataset of driving events, driving styles, and road conditions. The system effectively detects potential risks and helps mitigate the frequency and impact of accidents. The primary goal is to ensure the safety of drivers and vehicles. Collecting data involved gathering information on three key road events: normal street and normal drive, speed bumps, circular yellow speed bumps, and three aggressive driving actions: sudden start, sudden stop, and sudden entry. The gathered data is processed and analyzed using a machine learning system designed for limited power and memory devices. The developed system resulted in 91.9% accuracy, 93.6% precision, and 92% recall. The achieved inference time on an Arduino Nano 33 BLE Sense with a 32-bit CPU running at 64 MHz is 34 ms and requires 2.6 kB peak RAM and 139.9 kB program flash memory, making it suitable for resource-constrained embedded systems.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Harnessing WebAssembly for Real-time Stateless Streaming PipelinesChristina Lin
Traditionally, dealing with real-time data pipelines has involved significant overhead, even for straightforward tasks like data transformation or masking. However, in this talk, we’ll venture into the dynamic realm of WebAssembly (WASM) and discover how it can revolutionize the creation of stateless streaming pipelines within a Kafka (Redpanda) broker. These pipelines are adept at managing low-latency, high-data-volume scenarios.
Harnessing WebAssembly for Real-time Stateless Streaming Pipelines
IDEC thay thế PLC dòng FC4A, FC5A bằng dòng PLC mới FC6A
1. From FC4A/5A series MICROSmart programmable controller to
FC6A series MICROSmart programmable controller
From FC4A/5A series MICROSmart programmable controller to
FT1A series SmartAXIS Low-end controller
Replacement Manual
2. 2
Introduction.................................................................................................................................................... 3
CPU module selection table .......................................................................................................................... 5
Expansion module selection table............................................................................................................... 10
I/O number list ............................................................................................................................................. 14
External dimensions .................................................................................................................................... 15
Wiring........................................................................................................................................................... 21
Program conversion (FC4A/5A series -> FC6A series)............................................................................... 25
Compatibility table (FC4A/5A series -> FC6A series).................................................................................. 29
Function settings .......................................................................................................................29
PID module setting ....................................................................................................................29
Basic instructions ......................................................................................................................30
Advanced instructions ...............................................................................................................31
Macro instructions .....................................................................................................................33
Special devices .........................................................................................................................34
Program conversion (FC4A/5A series -> FT1A series) ............................................................................... 46
Compatibility table (FC4A/5A series -> FT1A series) .................................................................................50
Function settings .......................................................................................................................50
Basic instructions ......................................................................................................................51
Advanced instructions ...............................................................................................................52
Macro instructions .....................................................................................................................54
Special devices .........................................................................................................................55
Device I/O number table.............................................................................................................................. 63
Contents
3. 3
About this document
This document is a manual for replacing the FC4A/5A series MICROSmart programmable controller
with the FC6A series or the FT1A series SmartAXIS Low-end controller. Refer to this document
together with the FC6A Series Catalog (EP1575) and the All-in-One Type Users’ Manual for FC6A
Series (FC9Y-B1722) or FT1A Series Catalog (EP1527) and Pro/Lite Users’ Manual for FT1A Series
(FC9Y-B1378).
For customers who mainly use the 10/16/24-I/O type of the FC4A/5A series and do not need
to expand the number of I/Os, it is recommended to replace it with the FT1A series.
Replacement with FC6A series and FT1A series
• Dimensions are different among the FC4A/5A, FC6A, and FT1A series. Refer to [External
dimensions in page 15].
• Power supply and I/O terminal sizes or connector shapes are different among the FC4A/5A,
FC6A, and FT1A series. Thus, recommended wires and ferrules for wiring are partially different
depending on the series. Refer to [Wiring in page 21].
• One serial port (selected from either RS232C or RS485) is built in the FC6A series CPU module.
A maximum of three (40-I/O type only) serial communications can be performed by using a
communication cartridge (FC6A-PC1/PC3). No serial port is built in the FT1A series. Except the
12-I/O type, a maximum of one serial communication can be performed for the 24-I/O type and
a maximum of two for the 40/48-IO type by using a communication cartridge (FT1A-PC1/PC3).
• The basic number of inputs/outputs built in the CPU module is different between the FC4A/5A
series and the FC6A series. Inputs/outputs could not be expanded beyond the basic number of
I/Os in some types of the FC4A/5A series. However, I/Os can be expanded in all the CPU
modules of the FC6A series. The Maximum I/Os depends on the combination of expansion
modules to be connected. Select the modules in consideration of this points. For the FT1A
series, I/Os cannot be expanded beyond the basic number of I/Os. Refer to [CPU module
selection table in page 5].
• Expansion modules may have different detailed specifications even if they are recommended
models for replacement. Refer to [Expansion module selection table in page 10].
• A replacement module for the FC4A series AS-Interface master module is not available.
• The program capacities are different among the FA4A/5A, FC6A, and FT1A series. Refer to
[CPU module selection table in page 5].
• A clock is built in the CPU module for the FC6A series and that for the FT1A series. An external
clock cartridge is not required.
• The FC6A series uses a primary battery and the FT1A series uses a secondary battery as the
backup battery. In the FC6A series, if the battery has run down and it needs to be replaced, the
“BAT” is indicated by LED when the power is turned on again. (The standard replacement cycle
is approximately four years regardless of the backup time while the power is OFF.)
• The FC6A series does not support modem communication, Modbus ASCII communication, and
Modbus TCP communication via a serial communication port.
Introduction
4. 4
• To use the e-mail function and the web server function in the FC6A All-in-One type CPU module,
HMI module (FC6A-PH1) is required besides CPU module.
• The web server function provided for the FC6A series HMI module (FC6A-PH1) does not
support downloading from the users’ web pages.
Introduction
5. 5
Selection table for changing from the FC4A/5A series All-in-One type to the FC6A series All-in-One type
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed
basic
command
(ns)
Number of
expandable
units
Max.
I/Os
Width
mm
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed
basic
command
(ns)
Number of
expandable
units
Max.
I/Os
Width
mm
FC4A
-C10R2C
24 VDC
0.8K
6 pts. input and 4 pts.
relay output (2A)
3 pts.:COM0
1 pts.:COM1
1,000 Not possible 10 80
FC6A-
C16R1CE
24 VDC
9K (48K)
*1
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
3 pts.:COM1
42
4(12) *2
144
(400) *2
95
FC5A
-C10R2C
2.3K 700 Not possible 10 80
FC4A
-C16R2C
2.5K
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
2 pts.:COM1
1 pts.:COM2
1,000 Not possible 16 80
FC5A
-C16R2C
4.5K 700 Not possible 16 80
FC4A
-C24R2C
4.5K
14 pts. input and 0 pts.
relay output (2A)
4 pts.:COM0
4 pts.:COM1
1 pts.:COM2
1 pts.:COM3
1,000 4 88 95
FC6A-
C24R1CE
14 pts. input and 10 pts.
relay output (2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
7(15) *2
248
(504) *2
110
FC5A
-C24R2C
9K 700 4 88 95
FC4A
-C10R2
100 to
240
VAC
0.8K
6 pts. input and 4 pts.
relay output (2A)
3 pts.:COM0
1 pts.:COM1
1,000 Not possible 10 80
FC6A-
C16R1AE
100 to
240
VAC
9K (48K)
*1
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
3 pts.:COM1
42
4(12) *2
144
(400) *2
95
FC5A
-C10R2
2.3K 700 Not possible 10 80
FC4A
-C16R2
2.5K
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
2 pts.:COM1
1 pts.:COM2
1,000 Not possible 16 80
FC5A
-C16R2
4.5K 700 Not possible 16 80
FC4A
-C24R2
4.5K
14 pts. input and 10 pts.
relay output (2A)
4 pts.:COM0
4 pts.:COM1
1 pts.:COM2
1 pts.:COM3
1,000 4 88 95
FC6A-
C24R1AE
14 pts. input and 10 pts.
relay output (2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
7(15) *2
248
(504) *2
110
FC5A
-C24R2
9K 700 4 88 95
*1 The value in parentheses ( ) is the steps when the downloading function is not used during
running.
*2 The value in parentheses ( ) is the number of expandable units and the number of inputs/outputs
when combined with the expansion interface module.
CPU module selection table
6. 6
Selection table for changing from the FC4A/5A series All-in-One type to the FC6A series All-in-One type
(Continued)
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed
basic
command
(ns)
Number of
expandabl
e units
Max.
I/Os
Width
mm
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed
basic
command
(ns)
Number of
expandable
units
Max.
I/Os
Width
mm
FC5A
-C10R2D
DC
12V
2.3K
6pts.input
4pts.relay
output(2A)
3pts.:COM0
1pts.:COM1
700
Not
possible
10 80
FC6A-
C40R1DE
DC
12V
9K
(48K)
*1
24pts.input
16pts.relay output(2A)
4pts.:COM0
4pts.:COM1
4pts.:COM2
4pts.:COM3
42
7(15)
*2
264
(520)
*2
163
FC5A
-C16R2D
4.5K
9pts.input
7pts.relay
output(2A)
4pts.:COM0
2pts.:COM1
1pts.:COM2
700
Not
possible
16 80
FC5A
-C24R2D
9K
14pts.input
10pts.relay
output(2A)
4pts.:COM0
4pts.:COM1
1pts.:COM2
1pts.:COM3
700
Not
possible
24 95
*1 The value in parentheses ( ) is the steps when the downloading function is not used during
running.
*2 The value in parentheses ( ) is the number of expandable units and the number of inputs/outputs
when combined with the expansion interface module.
CPU module selection table
7. 7
Selection table for changing from the FC4A/5A series Slim type to the FC6A series All-in-One type
FC4A/5A
series No.
Main specifications
Recommended
FC6A series
No. for
replacement
Main specifications
Power
supply
voltag
e
Program
capacity
(steps)
I/O specifications
Processing
speed basic
command
(ns)
Number of
expandable
units
Max.
I/Os
Width
mm
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processi
ng
speed
basic
comman
d (ns)
Number of
expandable
units
Max.
I/Os
Width
mm
FC4A
-D20RK1
24
VDC
5.2K
12 pts. input and 6
pts. output relay
(2A)
3 pts.:COM1
2 pts.:COM2
1 pts.:COM3
2 pts. output
transistor
sink (0.3A)
2 pts.:COM0
1,000 7 148
47.5
FC6A-
C24R1CE
24
VDC
9K (48K)
*1
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
42 7 (15) *2
248
(504)
*2
110
FC6A-
C24K1CE
14 pts. input
and 10 pts.
output
transistor sink
(0.5A)
10 pts.:COM
FC4A
-D20RS1
5.2K
12 pts. input and 6
pts. output relay
(2A)
3 pts.:COM1
2 pts.:COM2
1 pts.:COM3
2 pts. output
transistor source
(0.3A)
2 pts.:COM0
FC6A-
C24R1CE
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
FC6A-
C24P1CE
14 pts. input
and 10 pts.
output
transistor
source (0.5A)
10 pts.:COM
FC5A
-D16RK1
10.4K
8 pts. input and 6
pts. output relay
(2A)
3 pts.:COM1
2 pts.:COM2
1 pts.:COM3
2 pts. output
transistor sink
(0.3A)
2 pts.:COM0
56 7 (15) *2
240
(496)
*2
FC6A-
C24R1CE
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
FC6A-
C24K1CE
14 pts. input
and 10 pts.
output
transistor sink
(0.5A)
10 pts.:COM
FC5A
-D16RS1
10.4K
8 pts. input and 6
pts. output relay
(2A)
3 pts.:COM1
2 pts.:COM2
1 pts.:COM3
2 pts. output
transistor source
(0.3A)
2 pts.:COM0
FC6A-
C24R1CE
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
FC6A-
C24P1CE
14 pts. input
and 10 pts.
output
transistor
source (0.5A)
10 pts.:COM
*1 The value in parentheses ( ) is the steps when the downloading function is not used during
running.
*2 The value in parentheses ( ) is the number of expandable units and the number of inputs/outputs
when combined with the expansion interface module.
CPU module selection table
8. 8
Selection table for changing from the FC4A/5A series Slim type to the FC6A series All-in-One type
(Continued)
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed basic
command
(ns)
Number
of
expanda-
ble units
Max.
I/Os
Width
mm
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed basic
command
(ns)
Number
of
expanda-
ble units
Max.
I/Os
Width
mm
FC5A
-D12K1E
*3
24 VDC
21.3K
8 pts. input and
4 pts. output
transistor
sink (0.3A)
4 pts.:COM
56
7 (15)
*2
236
(492
) *2
47.5
FC6A-
C16K1CE
24
VDC
9K
(48K)*1
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
42
4 (15)
*2
144
(400)
*2
95
FC6A-
C24K1CE
14 pts. input
and 10 pts.
output
transistor
sink (0.5A)
10 pts.:COM
7 (15)
*2
248
(504)
*2
110
FC5A
-D12S1E
*3
21.3K
8 pts. input and
4 pts. output
transistor
source (0.3A)
4 pts.:COM
FC6A-
C16P1CE
14 pts. input
and 10 pts.
output relay
(2A)
4 pts.:COM0
4 pts.:COM1
2 pts.:COM2
4 (15)
*2
144
(400)
*2
95
FC6A-
C24P1CE
14 pts. input
and 10 pts.
output
transistor
source (0.5A)
10 pts.:COM
7 (15)
*2
248
(504)
*2
110
*1 The value in parentheses ( ) is the steps when the downloading function is not used during
running.
*2 The value in parentheses ( ) is the number of expandable units and the number of inputs/outputs
when combined with the expansion interface module.
*3 The FC6A series All-in-One type does not have a web server function. To use a web server
function, connect an HMI module (FC6A-PH1).
CPU module selection table
9. 9
Selection table for changing from the FC4A/5A series All-in-One type to the FT1A series
FC4A/5A
series No.
Main specifications
Recommended
FT1A series No.
for replacement
Main specifications
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed
basic
command
(ns)
Number of
expandable
units
Width
mm
Power
supply
voltage
Program
capacity
(steps)
I/O specifications
Processing
speed basic
command
(ns)
Number of
expandable
units
Width
mm
FC4A
-C10R2C
24 VDC
0.8K
6 pts. input and 4 pts.
relay output (2A)
3 pts.:COM0
1 pts.:COM1
1,000
Not
possible
80
FT1A
-B12RA
24
VDC
3K
8 pts. input and 4 pts.
relay output (10A)
4 pts. independent
common
850
Not
possible
76
FC5A
-C10R2C
2.3K 700
Not
possible
80
FC4A
-C16R2C
2.5K
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
2 pts.:COM1
1 pts.:COM2
1,000
Not
possible
80
FT1A
-B24RA
11.85K
16 pts. input and 4 pts.
relay output (10A)
4 pts. independent
common
4 pts. relay output (2A)
4 pts.:COM4
119
FC5A
-C16R2C
4.5K 700
Not
possible
80
FC4A
-C24R2C
4.5K
14 pts. input and 10
pts. relay output (2A)
4 pts.:COM0
4 pts.:COM1
1 pts.:COM2
1 pts.:COM3
1,000 4 95
FC5A
-C24R2C
9K 700 4 95
FC4A
-C10R2
100 to
240
VAC
0.8K
6 pts. input and 4 pts.
relay output (2A)
3 pts.:COM0
1 pts.:COM1
1,000
Not
possible
80
FT1A
-B12RA
100
to
240
VAC
3K
8 pts. input and 4 pts.
relay output (10A)
4 pts. independent
common
850
Not
possible
76
FC5A
-C10R2
2.3K 700
Not
possible
80
FC4A
-C16R2
2.5K
9 pts. input and 7 pts.
relay output (2A)
4 pts.:COM0
2 pts.:COM1
1 pts.:COM2
1,000
Not
possible
80
FT1A
-B24RA
11.85K
16 pts. input and 4 pts.
relay output (10A)
4 pts. independent
common
4 pts. relay output (2A)
4 pts.:COM4
119
FC5A
-C16R2
4.5K 700
Not
possible
80
FC4A
-C24R2
4.5K
14 pts. input and 10
pts. relay output (2A)
4 pts.:COM0
4 pts.:COM1
1 pts.:COM2
1 pts.:COM3
1,000 4 95
FC5A
-C24R2
9K 700 4 95
CPU module selection table
10. 10
FC4A/5A series digital I/O module -> FC6A series digital I/O module
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Terminal shape
Terminal
I/O specifications
Width
mm
Terminal
I/O specifications
Width
mm
Number of
pins
Pitch (mm)
Number
of pins
Pitch (mm)
FC4A-N08B1 11 3.81
8 pts. input
8 pts./1 common
23.5 FC6A-N08B1 11 5.08
8 pts. input
8 pts./1 common
23.6 Different
FC4A-N16B1 10x2 3.81
16 pts. input
16 pts./1 common
23.5 FC6A-N16B1 10x2 3.81
16 pts. input
16 pts./1 common
23.6 No change
FC4A-N16B3 20
MIL
Connector
16 pts. input
16 pts./1 common
17.6 FC6A-N16B3 20
MIL
Connector
16 pts. input
16 pts./1 common
17.6 No change
FC4A-N32B3 20x2
MIL
Connector
32 pts. input
16 pts./1 common
29.7 FC6A-N32B3 20x2
MIL
Connector
32 pts. input
16 pts./1 common
30.2 No change
FC4A-N08A11 11 3.81
8 pts. input
4 pts./1 common
23.5 FC6A-N08A11 11 5.08
8 pts. input
4 pts./1 common
23.6 Different
FC4A-R081 11 3.81
8 pts. output relay (2A)
8 pts./1 common
23.5 FC6A-R081 11 5.08
8 pts. output relay (2A)
8 pts./1 common
23.6 Different
FC4A-R161 10x2 3.81
16 pts. output relay (2A)
16 pts./1 common
23.5 FC6A-R161 10x2 3.81
16 pts. output relay (2A)
16 pts./1 common
23.6 No change
FC4A-T08K1 11 3.81
8 pts. output transistor sink
(0.3A)
8 pts./1 common
23.5 FC6A-T08K1 11 5.08
8 pts. output transistor sink
(0.5A)
8 pts./1 common
23.6 Different
FC4A-T08S1 11 3.81
8 pts. output transistor
source (0.3A)
8 pts./1 common
23.5 FC6A-T08S1 11 5.08
8 pts. output transistor source
(0.5A)
8 pts./1 common
23.6 Different
FC4A-T16K3 20
MIL
Connector
16 pts. output transistor
sink (0.1A)
16 pts./1 common
17.6 FC6A-T16K3 20
MIL
Connector
16 pts. output transistor sink
(0.1A)
16 pts./1 common
17.6 No change
FC4A-T16S3 20
MIL
Connector
16 pts. output transistor
source (0.1A)
16 pts./1 common
17.6 FC6A-T16S3 20
MIL
Connector
16 pts. output transistor source
(0.1A)
16 pts./1 common
17.6 No change
FC4A-T32K3 20x2
MIL
Connector
32 pts. output transistor
sink (0.1A)
16 pts./1 common
29.7 FC6A-T32K3 20x2
MIL
Connector
32 pts. output transistor sink
(0.1A)
16 pts./1 common
30.2 No change
FC4A-T32S3 20x2
MIL
Connector
32 pts. output transistor
source (0.1A)
16 pts./1 common
29.7 FC6A-T32S3 20x2
MIL
Connector
32 pts. output transistor source
(0.1A)
16 pts./1 common
30.2 No change
FC4A-M08BR1 11 3.81
4 pts. input
4 pts./1 common
4 pts. output relay (2A)
4 pts./1 common
23.5 FC6A-M08BR1 11 5.08
4 pts. input
4 pts./1 common
4 pts. output relay (2A)
4 pts./1 common
23.6 Different
FC4A-M24BR2 11,17 3.81
16 pts. input
16 pts./1 common
8 pts. output relay (2A)
8 pts./1 common
39.1 FC6A-M24BR2 11,17 3.81
16 pts. input
16 pts./1 common
8 pts. output relay (2A)
8 pts./1 common
39.2 Different
Expansion module selection table
11. 11
FC4A/5A series analog input module -> FC6A series analog input module
*1 The resolution will be lowered. For voltage input: in increments of 0.2 mV (FC4A series) -> 2.44
mV (FC6A series), for current input: in increments of 0.32 uA
(FC4A series) -> 3.91 uA (FC6A series)
FC4A/5A series analog output module -> FC6A series analog output module
*1 When replaced from FC4A-K2C1, the resolution will be lowered.
For voltage input: in increments of 0.2 mV (FC4A series) -> 2.44 mV (FC6A series)
For current input: in increments of 0.32 uA (FC4A series) -> 3.91 uA (FC6A series)
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Terminal shape
Analog input specifications
Width
mm
Analog input specifications
Width
mm
I/O
points
Type Resolution
I/O
points
Type Resolution
FC4A-J2A1 2
Voltage (0 to 10 V)
Current (4 to 20 mA)
4,096 23.5 FC6A-J2C1 2
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20mA)
65,536 23.6 Different
FC4A-J8C1 8
Voltage (0 to 10 V)
Current (4 to 20 mA)
50,000 23.5 FC6A-J8A1 8
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
4,096
*1
23.6 No change
FC4A-J4CN1 4
Voltage (0 to 10 V)
Current (4 to 20 mA)
Temperature measuring
resistor
(Pt100, Pt1000, Ni100,
Ni1000)
Thermocouple (K, J, T)
50,000 23.5 FC6A-J4CN1 4
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
65,536
23.6
No change
However, there is a difference in
terminal layout
Temperature measuring
resistor
(Pt100, Pt1000, Ni100,
Ni1000)
Thermocouple (K, J, R, S,
B, E, T, N, C)
0.1ºC
FC4A-J8AT1 8
Thermistor
(NTC: -50 to 150°C, PTC: 0
to 100 k )
25 23.5 FC6A-J8CU1 8
Thermocouple (K, J, R, S,
B, E, T, N, C)
0.1ºC
23.6 No change
Thermistor
(NTC: -90 to 150°C, PTC
100 to 10 k )
Resistance
(100 to 32 k )
1
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Terminal shape
Analog output specifications
Width
mm
Analog output specifications
Width
mm
I/O
points
Type Resolution
I/O
points
Type Resolution
FC4A-K1A1 1
Voltage (0 to 10
V)
Current (4 to 20
mA)
4,096 23.5
FC6A-K4A1 4
Voltage (0 to
10 V)
Voltage (-10 to
+10 V)
Current (0 to
20 mA)
Current (4 to
20 mA)
4096 *1 23.6 DifferentFC4A-K2C1 2
Voltage (0 to 10
V)
Current (4 to 20
mA)
50,000 23.5
FC4A-K4A1 4
Voltage (0 to 10
V)
Current (4 to 20
mA)
4,096 23.5
Expansion module selection table
12. 12
FC4A/5A series analog I/O module -> FC6A series analog I/O module
*1 With regard to the input taking system, single end input is used for the FC6A-L03CN1, while
differential input is used for FC4A-L03AP1.
Because single end input is susceptible to common mode noise, it is recommended to use
insulation type thermocouples.
FC4A/5A series
No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Terminal shape
Analog I/O specifications
Width
mm
Analog I/O specifications
Width
mm
I/O
points
Type Resolution
I/O
points
Type Resolution
FC4A-L03A1 3
2 pts. input
Voltage (0 to 10 V)
Current (4 to 20 mA)
1 pts. output
Voltage (0 to 10 V)
Current (4 to 20 mA)
4,096 23.5
FC6A-L06A1 6
4 pts. input
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
2 pts. output
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
4.096 23.6 No change
FC6A-L03CN1 3
2 pts. input
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
65,536
23.6 Different
Temperature measuring
resistor
(Pt100, Pt1000, Ni100,
Ni1000)
Thermocouple (K, J, R, S,
B, E, T, N, C)*1
0.1°C
1 pts. output
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
4,096
FC4A-L03AP1 3
2 pts. input
Temperature
measuring resistor
(Pt100)
Thermocouple (K, J,
T)
0.1ºC
23.5 FC6A-L03CN1 3
2 pts. input
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
65,536
23.6 Different
Temperature measuring
resistor
(Pt100, Pt1000, Ni100,
Ni1000)
Thermocouple (K, J, R, S,
B, E, T, N, C)*1
0.1°C
1 pts. output
Voltage (0 to 10 V)
Current (4 to 20 mA)
4,096 1 pts. output
Voltage (0 to 10 V)
Voltage (-10 to +10 V)
Current (0 to 20 mA)
Current (4 to 20 mA)
4,096
Expansion module selection table
13. 13
FC4A/5A series PID module -> FC6A series PID module
FC5A series communication module -> FC6A series communication cartridge
A communication module for the FC6A series is not available. If it is necessary to expand the
communication port, use a communication cartridge. However, the number of cartridges that can be
installed is a maximum of two ports for the 40 pts All-in-One type and one port for 24 pts and 16 pts
All-in-One types.
FC4A/5A
series No.
Main specifications
Recommended
FC6A series No.
for replacement
Main specifications
Terminal shape
Analog I/O
specifications
Analog I/O specifications
Width
mm
Analog I/O specifications
Width
mm
I/O
points
Type Resolution
I/O
points
Type Resolution
FC5A-F2MR1 4
2 pts. input
Voltage (0 to 1 V, 0 to 5 V,
1 to 5 V, 0 to 10 V)
Current (0 to 20 mA, 4 to
20 mA)
Temperature measuring
resistorThermocouple
2 pts. relay output (5A)
2 pts. independent
common
Input
12,000
23.5 FC6A- F2MR1 4
2 pts. input
Voltage (0 to 1 V, 0 to 5 V,
1 to 5 V, 0 to 10 V)
Current (0 to 20 mA, 4 to
20 mA)
Temperature measuring
resistorThermocouple
2 pts. relay output (5A)
2 pts. independent
common
Input
12,000
23.6 Different
FC5A-F2M1 4
2 pts. input
Voltage (0 to 1 V, 0 to 5 V,
1 to 5 V, 0 to 10 V)
Current (0 to 20 mA, 4 to
20 mA)
Temperature measuring
resistorThermocouple
2 pts. output
Voltage output (12 V)
Current output (4 to 20
mA)
Input
12,000
Output
1,000
23.5 FC6A-F2M1 2
2 pts. input
Voltage (0 to 1 V, 0 to 5 V,
1 to 5 V, 0 to 10 V)
Current (0 to 20 mA, 4 to
20 mA)
Temperature measuring
resistorThermocouple
2 pts. output
Voltage output (12 V)
Current output (4 to 20
mA)
Input
12,000
Output
1,000
23.6 Different
FC4A/5A series No.
Main specifications
Recommended
FC6A series
No. for
replacement
Main specifications
Communication specifications Communication specifications
Communication
specifications
Communication range
Communication speed
Isolation from internal
circuit
Communication
specifications
Communication range
Communication speed
Isolation from internal
circuit
FC5A-SIF2 RS232C
Max. 10 m
Max. 115.2 Kbps
Isolated FC6A-PC1 RS232C
Max. 50 m
Max. 115.2 Kbps
Not isolated
FC5A-SIF4 RS485
Max. 1,200 m
Max. 115.2 Kbps
Isolated FC6A-PC3 RS485
Max. 200 m
Max. 115.2 Kbps
Not isolated
Expansion module selection table
14. 14
The ranges of input and output numbers for the FC4A/FC5A series and the FC6A series are listed
below.
Model
Input Output
Existing
number
Reserved
number
Existing
number
Reserved
number
FC6A-C16R1AE/C16R1CE/C16K1CE/C16P1CE
I0 to I11
I12 to Y27
Q0 to Q6
Q7 to Q27
I30 to I507 Q30 to Q507
FC6A-C24R1AE/C24R1CE/C24K1CE/C24P1CE
I0 to I15
I16 to I27
Q0 to Q11
Q12 to Q27
I30 to I627 Q30 to Q627
FC6A-C40R1AE/C40R1CE/C40K1CE/C40P1CE
I0 to I27 Q0 to Q17
Q20 to Q27
I30 to I627 Q30 to Q627
FC5A-C10R2/C10R2C
FC4A-C10R2/C10R2C
I0 to I5 Q0 to Q3
FC5A-C16R2/C16R2C
FC4A-C16R2/C16R2C
I0 to I10 Q0 to Q6
FC5A-C24R2/C24R2C
FC4A-C24R2/C24R2C
I0 to I15
I16 to I27
Q0 to Q11
Q12 to Q27
I30 to I107 Q30 to Q107
The ranges of input and output numbers for the FC4A/FC5A series and the FT1A series are listed
below.
Model
Input Output
Existing
number
Reserved
number
Existing
number
Reserved
number
FT1A-B12RA/B12RC I0 to I7 Q0 to Q3
FT1A-B24RA/B24RC I0 to I15 Q0 to Q7
FT1A-B40RKA/B40RSA/B40RC I0 to I27 Q0 to Q17
FT1A-B48KA/B48SA/B48KC/B48SC I0 to I35 Q0 to Q21
FC5A-C10R2/C10R2C
FC4A-C10R2/C10R2C
I0 to I5 Q0 to Q3
FC5A-C16R2/C16R2C
FC4A-C16R2/C16R2C
I0 to I10 Q0 to Q6
FC5A-C24R2/C24R2C
FC4A-C24R2/C24R2C
I0 to I15
I16 to I27
Q0 to Q11
Q12 to Q27
I30 to I107 Q30 to Q107
I/O number list
15. 15
External dimensions of FC4A/5A series MICROSmart
All-in-One type CPU modules
FC4A-C10R2*/C16R2* FC4A-C24R2*
FC5A-C10R2*/C16R2* FC5A-C24R2*
Slim type CPU module
FC4A-D20*1 FC4A-D40*3
FC5A-D16R*1 FC5A-D32*3
FC4A-D20*3 FC5A-D12*1E
*The dimension when the hook is pulled out is 8.5 mm.
Unit: mm
External dimensions
17. 17
Optional modules
Expansion interface modules
FC4A-HPC1
FC4A-HPC2
FC4A-HPC3
FC4A-HPH1
FC5A-EXM1M FC5A-EXM1S
FC5A-EXM2
*1The dimension when the hook is pulled out is 8.5 mm.
*2 It is the standard length when the cable is bent.
External dimensions
18. 18
External dimensions of FC6A series MICROSmart
All-in-One type CPU modules
Expansion modules
FC6A-C16*1*E FC6A-C24*1*E
FC6A-C40*1*E
FC6A-K4A1
FC6A-L03CN1
FC6A-J2C1
FC6A-M08BR1
FC6A-N08A11
FC6A-N08B1
FC6A-R081
FC6A-T08K1
FC6A-T08P1
FC6A-J4A1
FC6A-J8A1
FC6A-J4CN1
FC6A-J8CU1
FC6A-L06A1
FC6A-N16B1
FC6A-R161
FC6A-T16K1
FC6A-T16P1
*The dimension when the hook is pulled out is 9.3 mm.
Unit: mm
External dimensions
19. 19
Optional modules
FC6A-N16B3 FC6A-T16K3
FC6A-T16P3
FC6A-N32B3 FC6A-T16K3
FC6A-T16P3
FC6A-F2MR2 FC6A-F2M2
FC6A-M24BR2
*The dimension when the hook is pulled out is 9.3 mm.
FC6A-PH1
FC6A-PC1/FC6A-PC3
FC6A-PJ2A/FC6A-PK2AV
FC6A-PK2AW/FC6A-PJ2CP
External dimensions
20. 20
Expansion interface modules
External dimensions of FT1A series SmartAXIS
FC6A-EXM2
*The dimension when the hook is pulled out is 9.3 mm.
FT1A-B12RA
*The dimension when the hook is pulled out is 9.3 mm.
FT1A-B12RC
FT1A-B24RA FT1A-B24RC
External dimensions
21. 21
Wiring terminal
Module configurations and wiring terminals for power supply, input, and output of the FC4A/5A
series and the FC6A series are shown below.
Combination of the FC4A/FC5A series Slim type and expansion modulesFC4A/FC5A series All-in-One type
Power supply terminal
Grounding terminal
Output terminal
Input terminal
Power supply terminal
Grounding terminalI/O terminal
• Fixed terminal blocks are used for all the terminals of the FC4A/5A All-in-One type.
• Removable terminal blocks are used for all the terminals of the FC4A/5A slim type except the power supply terminal.
• Removable terminal blocks are used for all the FC4A/5A series expansion modules except FC4A-M24BR2 and
FC5A-F2M(R)2.
Input module, output module, I/O module
Wiring
Combination of the FC6A series All-in-One type and expansion modules
• Removable terminal blocks are used for all the FC6A series All-in-One type and expansion modules.
Input module, output module, I/O module
Output terminal
Power supply terminal
Grounding terminal
Input terminal
22. 22
Module configurations and wiring terminals for power supply, input, and output of the FC4A/5A
series and the FT1A series are shown below.
FT1A series
Input terminal
Power supply terminal
Grounding terminal
Output terminal
• Fixed terminal blocks are used for all the terminals of the FT1A series.
Wiring
Combination of the FC4A/FC5A series Slim type and expansion modulesFC4A/FC5A series All-in-One type
Power supply terminal
Grounding terminal
Output terminal
Input terminal
Power supply terminal
Grounding terminalI/O terminal
• Fixed terminal blocks are used for all the terminals of the FC4A/5A All-in-One type.
• Removable terminal blocks are used for all the terminals of the FC4A/5A Slim type except the power supply terminal.
• Removable terminal blocks are used for all the FC4A/5A series expansion modules except FC4A-M24BR2 and
FC5A-F2M(R)2.
Input module, output module, I/O module
23. 23
Recommended wires and terminals
Wires and ferrules recommended for the FC4A/5A series are listed in the following table.
• FC4A/5A series CPU modules
• FC4A/5A series expansion modules
Recommended wires and ferrules in the following table should be used for connection with the
power supply, I/Os built in the CPU module, or expansion module I/Os for the FC6A series. For
some wire and ferrule types, the currently used ones can be used continuously.
• FC6A series All-in-One type
Terminal
Recommended wires [recommended ferrules (manufactured by PHOENIX CONTACT)]
All-in-One type Slim type
Power
supply
European type
terminal
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 0.75-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire connection
Grounding UL1007AWG16: AI1.5-8
I/O
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire
connection
UL1007AWG18: AI 0.75-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire
connection
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire
connection
Terminal Recommended wires [recommended ferrules (manufactured by PHOENIX CONTACT)]
Power
supply
European type
terminal
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
Grounding UL1007AWG18: AI1-10,AI1-8
I/O
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
Terminal Recommended wires [recommended ferrules (manufactured by PHOENIX CONTACT)]
Power supply
European type
terminal
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 0.75-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire connection
Grounding UL1007AWG16: AI1.5-8
I/O
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 0.75-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire connection
CAN
communication
UL1007AWG22: AI 0.34-10 for 1-wire connection
UL1007AWG20: AI 0.5-10 for 1-wire connection
AI-TWIN 2 x 0.5-10 for 2-wire connection
UL1007AWG18: AI 0.75-10 for 1-wire connection
AI-TWIN 2 x 0.75-10 for 2-wire connection
Wiring
24. 24
• FC6A series expansion modules
• FT1A series expansion modules
The following table shows cross section conversion for AWG notation.
Terminal
Recommended wires [recommended ferrules (manufactured by PHOENIX CONTACT)]
5.08 mm pitch terminal block 3.81 mm pitch terminal block
Power
supply
European type
terminal
UL1007AWG22: AI 0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 0.75-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire
connection
UL1007AWG22: AI 0.34-10/0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-10/0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-10 for 2-wire
connection
Grounding UL1007AWG16: AI1.5-8 UL1007AWG18: AI1-10,AI1-8
I/O
UL1007AWG22: AI 0.34-10 for 1-wire connection
UL1007AWG20: AI 0.5-10 for 1-wire connection
AI-TWIN 2 x 0.5-10 for 2-wire
connection
UL1007AWG18: AI 0.75-10 for 1-wire connection
AI-TWIN 2 x 0.75-10 for 2-wire
connection
UL1007AWG22: AI 0.34-10/0.34-8 for 1-wire connection
UL1007AWG20: AI 0.5-10/0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-10 for 2-wire
connection
Terminal
Recommended wires [recommended ferrules
(manufactured by PHOENIX CONTACT)]
Power
supply
European type
terminal
UL1007AWG24: AI 0.25-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 1-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire
connection
Grounding UL1007AWG16: AI1.5-8
I/O
UL1007AWG24: AI 0.25-8 for 1-wire connection
UL1007AWG20: AI 0.5-8 for 1-wire connection
AI-TWIN 2 x 0.5-8 for 2-wire connection
UL1007AWG18: AI 1-8 for 1-wire connection
AI-TWIN 2 x 0.75-8 for 2-wire
connection
AWG conversion table
AWG
Cross section
(mm2)
16 1.309
18 0.8226
20 0.5174
22 0.3256
Wiring
25. 25
Programming software
PLC programming software “WindLDR (Ver.8.0.0 or later)” included in our system integration
software “Automation Organizer” (series No.: SW1A-W1C) is used for the FC6A series as with the
FC4A/FC5A series.
The latest update file is published on our website. It is recommended to use the latest version of
“Automation Organizer” for program conversion.
http://us.idec.com/ProductSupport/Software.aspx
Program conversion for FC5A series
Some of the FC4A/FC5A series programs are incompatible with the FC6A series programs. Thus, it
is impossible to perform automatic conversion of all programs completely. Program conversion
should be performed according to the WindLDR model setting. By changing the model, instructions
that can be replaced automatically will be converted and instructions that need to be replaced
manually or cannot be replaced will remain unconverted.
Compatibility settings for function settings will be taken over. Settings that are not taken over will be
lost. Check the conversion results in the information window of WindLDR.
For details about the compatibility with each item of I/O numbers and special devices, refer to
[Compatibility table (FC4A/5A -> FC6A) in page 29].
Program uploading
If you do not have the ladder program file for the FC4A/5A series,
connect the main body of the FC4A/5A series to a PC (RS232
interface) via a PC interface cable (FC2A-KC4C) to upload (read
out) the program. The procedure is as follows.
Click [Upload] in the [Online] tab of WindLDR.
The upload window will appear. Click [OK].
FC2A-KC4C
Click [Upload].
Click [OK].
Program conversion (FC4A/5A series -> FC6A series)
26. 26
Conversion procedure
Open the program for the FC4A/5A series using WindLDR.
Click the [PLC type] icon in the [Configuration] tab.
In the displayed window, select the CPU module to be used after conversion and then click
[OK].
Conversion report
When conversion has been performed according to the procedure, the conversion report will be
output in the information window as shown in the example below.
When the mouse cursor is put on each item of the conversion report in the information window to
select the item, the cursor in the ladder program field will also move to the related ladder part in
conjunction. Edit the ladder part according to the warning contents.
Click [PLC Type].
Select a CPU module and
then click [OK].
The cursor moves in
conjunction.
Program conversion (FC4A/5A series -> FC6A series)
27. 27
Batch conversion of I/O numbers
Consecutive I/O numbers can be converted at a time. Use this function when I/Os of the FC6A
series CPU module are not used or when reserved numbers should be skipped.
1. Click [Replace] in the [Home] tab, and further, select [Replace].
2. In the displayed window, enter the I/O numbers before and after conversion in [Device] and the
I/O points to be converted in [Points to Replace]. If comments should also be moved, mark the
checkbox for [Replace comment].
3. Click [Replace].
Click [Replace] and select
[Replace] further.
Enter the I/O numbers
before and after conversion
and the number of points to
be converted.
Mark the checkbox for
[Replace comment] as
necessary.
Click [Replace].
Program conversion (FC4A/5A series -> FC6A series)
28. 28
4. The cursor will move to the I/O to be converted, and the confirmation window will appear. To
convert while confirming I/Os one by one, click [Yes]. To convert the remaining I/Os at a time
without confirming them, click [Yes to all].
The cursor moves to
the I/O to be
converted.
Click [Yes] or [Yes to
all] in the displayed
window.
Program conversion (FC4A/5A series -> FC6A series)
29. 29
Function settings
The available options for replacing of all setting items are shown in the table below.
Yes: Setting that is replaced automatically
Indirectly: Setting that needs to be replaced manually
No: Setting that cannot be replaced
Replaceability Function setting for FC4A/5A series FC6A series specifications
Yes Operation/stop control A function switch setting is added.
Yes Memory backup
Indirectly
Special input
High-speed
counter
Select from among six high-speed counter groups.
Yes Catch input They are automatically replaced with the same group numbers. However, change wiring
because the input terminal numbers are different.Yes Interrupt input
Indirectly
Frequency
measurement
Select it using the “Frequency measurement” function.
Yes Input filter
Yes Timer interruption
Indirectly/No*1 Communication port Some of the communication modes cannot be replaced. *1
No Communication refresh for ports 3 to 7 No setting is required because communication refresh is performed regularly.
No Communication option
It is not supported and cannot be used. Specify a constant as the slave number for each
communication mode setting, or specify or select using the data resister.
No Key matrix It is not supported and cannot be used. Use expansion I/O modules.
No Clock cartridge
A clock is built in the CPU module. Because the correction value is written at the time of
shipment, it is unnecessary to make the setting.
No Memory cartridge
It is not supported and cannot be used. User programs can be uploaded/downloaded
using an SD memory card. Make the setting from the setting window for the SD memory
card.
No Expansion modules An AS-Interface module is not supported and cannot be used.
Yes Device setting
Yes Program protection The old password can also be used if the program protection is not changed.
No Self-diagnosis The RUN LED blinking setting is not supported and cannot be used.
Yes Network setting
Yes E-mail setting It will be replaced with the e-mail setting for the HMI module setting.
Yes Network administration The Ping setting will be converted in a millisecond unit.
Indirectly Connection setting Make the settings for connection 1 to 8 (commonly used for the server/client).
Yes Web server It will be replaced with the web server setting for the HMI module setting.
*1 The following communication modes are not supported in the FC6A series and cannot be
replaced.
Modem communication, Modbus ASCII master/slave, Modbus TCP master/slave using
FC4A-SX5ES1J/E
PID module setting
The PID module set in the dialog for the FC5A series expansion module setting will be automatically
imported to the module configuration editor when the model is changed to the FC6A series. The
module series numbers before and after conversion are as follows.
FC5A series No. FC6A series No.
FC5A-F2MR1 FC6A-F2MR1
FC5A-F2M1 FC6A-F2M1
Compatibility table (FC4A/5A series -> FC6A series)
30. 30
Basic instructions
The available basic instructions for replacing are shown in the table below.
YES: Instruction that can be replaced automatically
NO : Instruction that cannot be replaced
Replaceability
Instruction for FC4A/5A
series
FC6A series specifications
Yes Normally open contact
Yes Normally closed contact
Yes OUT
Yes OUTN
Yes SET
Yes RST
Yes AND
Yes ANDN
Yes OR
Yes ORN
Yes AND•LOD
Yes OR•LOD
Yes BPS
Yes BRD
Yes BPP
Yes TML
Yes TIM
Yes TIMH
Yes TMS
Yes CNT
Yes CDP
Yes CUD
Yes CC=
Yes CC>=
Yes DC=
Yes DC>=
Yes SFR
Yes SFRN
Yes SOTU
Yes SOTD
Yes JMP
Yes JEND
Yes MCS
Yes MCR
Yes END
Compatibility table (FC4A/5A series -> FC6A series)
31. 31
Advanced instructions
The available advanced instructions for replacing are shown in the table below.
Yes: Compatible instruction that can be replaced automatically
Indirectly: Instruction that needs to be replaced manually
No: Instruction that cannot be replaced
Replaceability Instruction for FC4A/5A series FC6A series specifications
Yes MOV, MOVN
Yes IMOV, IMOVN
Yes IBMV, IBMVN
Yes BMOV
Yes NSET, NRS
Yes XCHG
Yes TCCST
Yes CMP* (*: =, <>, <, <=, >, >=)
Yes ICMP >=
Yes LC
Yes ADD, SUB
Yes MUL
Yes DIV
Yes ROOT
Yes INC, DEC
Yes SUM
Yes RNDM
Yes ANDW, ORW, XORW
Yes SFTL, SFTR
Yes ROTL, ROTR
Yes BCDLS
Yes WSFT
Yes HTOB, ATOB
Yes BTOH, ATOH
Yes HTOA, BTOA
Yes ENCO, DECO
Yes BCNT
Yes ALT
Yes CVDT
Yes DTDV
Yes DTCB
Yes SWAP
Yes DISP
Yes DGRD
Yes WKTBL
Yes WKTIM
Compatibility table (FC4A/5A series -> FC6A series)
32. 32
Replaceability Instruction for FC4A/5A series FC6A series specifications
Yes PULS
It will be replaced with the PULS instruction for which the corresponding
compatibility mode has been set.
Yes PWM
It will be replaced with the PWM instruction for which the corresponding
compatibility mode has been set. However, there are restrictions on the
upper limit/lower limit of frequency that can be output and the unit. Thus,
the output frequency will be an approximate value.
Yes ZRN
It will be replaced with the ZRN instruction for which the corresponding
compatibility mode has been set.
Yes RAMP
It will be replaced with the RAMP instruction for which the corresponding
compatibility mode has been set.
Indirectly TXD, RXD They support ports 1 to 3. Port 4 and later cannot be used.
Yes XYFS, CVXTY, CVYTX
Yes AVRG
Yes PID The PID instruction will be replaced.
Yes DTML, DTIM, DTMH, DTMS
Yes TTIM
Yes LABEL
Yes LJMP
Yes LCAL
Yes LRET
Yes DJNZ
Yes DI, EI
Yes IOREF
Yes HSCRF
Yes FRQRF
Yes COMRF
No RUNA, STPA
It is not supported and cannot be used. Insert an expansion module
according to the configuration used in the module configuration editor, and
set the data reister to be used from the analog parameter setting window.
Yes RAD
Yes DEG
Yes SIN, COS, TAN
Yes ASIN, ACOS, ATAN
Yes LOG10
Yes EXP
Yes LOGE
Yes POW
Yes FIFOF, FIEX, FOEX
Yes NDSRC
Yes TADD, TSUB
Yes HTOS, STOH
Yes HOUR
Yes NOP
Compatibility table (FC4A/5A series -> FC6A series)
33. 33
Macro instructions
The available macro instructions for replacing are shown in the table below.
Yes: Compatible instruction that can be replaced automatically
Indirectly: Instruction that needs to be replaced manually
No: Instruction that cannot be replaced
Replaceability Instruction Remarks
Yes MACRO
Yes CWWT, CWRD If there is no corresponding communication port, communication port 1 will be set.
No ANST
The FC6A series does not support ANST instructions. However, the analog module setting
set by an ANST instruction will be automatically imported to the module configuration editor
when the model is changed. Modules before and after conversion are as follows.
FC4A/5A series No. FC6A series No.
FC4A-J2A1 FC6A-J2C1
FC4A-J8C1 FC6A-J8A1
FC4A-J4CN1 FC6A-J4CN1
FC4A-J8AT1 FC6A-J8CU1
FC4A-K1A1
FC6A-K4A1FC4A-K2C1
FC4A-K4A1
FC4A-L03A1
FC6A-L03CN1
FC4A-L03AP1
Refer to *1 for precautions on model conversion of analog modules.
Yes PULSST
Yes PWMST
Yes RAMPST
Yes ZRNST
Yes PIDST
*1 Precautions on model conversion of analog modules
The analog module set by an ANST instruction will be automatically imported to the module
configuration editor. However, there are the following precautions. Check the setting after
conversion using the module configuration editor.
• The analog value and status data resister allocation in each channel will change. Allocation
in the FC6A series can be checked using the module configuration editor.
• The filter and scale settings for FC4A-J4CN1, FC4A-J8C1, and FC4A-J8AT1 will be lost.
• The analog input error range settings for FC4A-J4CN1 and FC4A-J8C1 will be lost.
• If binary data, centigrade, Fahrenheit, and resistance values are selected as the data type,
the analog value range might be changed after conversion.
Compatibility table (FC4A/5A series -> FC6A series)
34. 34
Special devices
The available special devices for replacing are shown in the table below..
Yes: Compatible device that can be replaced automatically
Indirectly: Device that needs to be replaced manually
No: Device that cannot be replaced
Special internal relay
Replaceability
Special
internal
relay
FC4A/5A series specifications FC6A series specifications
Yes M8000 Start Control
Yes M8001 1-s Clock Reset
Yes M8002 All Outputs OFF
Yes M8003 Carry (Cy) or Borrow (Bw)
Yes M8004 User Program Execution Error
Yes M8005 Communication Error
Yes M8006
Data Link Communication Prohibit Flag (Master
Station)
Yes M8007
Data Link Communication Initialize Flag (Master
Station)
Data Link Communication Stop Flag (Slave Station)
Yes M8010 Status LED
No M8011 HMI Write Prohibit Flag
It is not supported and cannot be used.
M8011 is defined as reserved.
No M8012 HMI Operation Prohibit Flag
It is not supported and cannot be used.
M8012 is defined as reserved.
Yes M8013 Calendar/Clock Data Write/Adjust Error Flag
Yes M8014 Calendar/Clock Data Read Error Flag
No M8015 Calendar/Clock Data Read Stop Flag
The CPU module uses the built-in
clock, which cannot be stopped. M8015
is defined as reserved.
Yes M8016 Calendar Data Write Flag
Yes M8017 Clock Data Write Flag
Yes M8020 Calendar/Clock Data Write Flag
Yes M8021 Clock Data Adjust Flag
Yes M8022
User Communication Receive Instruction Cancel Flag
(Port 1)
Yes M8023
User Communication Receive Instruction Cancel Flag
(Port 2)
Yes M8024 BMOV/WSFT Executing Flag
Yes M8025 Maintain Outputs While CPU Stopped
No M8026
Expansion Data Register Data Writing Flag (Preset
Range 1)
Use the recipe function. M8026 is
defined as User Communication
Receive Instruction Cancel Flag (Port
3), and M8027 as High-speed Counter
(Group 1/10).
No M8027
Expansion Data Register Data Writing Flag (Preset
Range 2)
Indirectly M8030 High-speed Counter (X0-X2) Comparison Output Reset There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 1/I0) near device allocation.
Indirectly M8031 High-speed Counter (X0-X2) Gate Input
Indirectly M8032 High-speed Counter (X0-X2) Reset Input/Preset Input
Indirectly M8033
User Communication Receive Instruction Cancel Flag
(Port 3)
Use M8026.
Indirectly M8034 High-speed Counter (X3) Comparison Output Reset There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 3/I3) near device allocation.
Indirectly M8035 High-speed Counter (X3) Gate Input
Indirectly M8036 High-speed Counter (X3) Reset Input
Compatibility table (FC4A/5A series -> FC6A series)
35. 35
Replaceability
Special
internal
relay
FC4A/5A series specifications FC6A series specifications
- M8037 Reserved
Indirectly M8040 High-speed Counter (X4) Comparison Output Reset There is no compatibility with the
high-speed counter.
Set and refer to the high-speed
counter (group 4/I4) near device
allocation.
Indirectly M8041 High-speed Counter (X4) Gate Input
Indirectly M8042 High-speed Counter (X4) Reset Input
- M8043 Reserved
Indirectly M8044 High-speed Counter (X5- X7) Comparison Output Reset There is no compatibility with the
high-speed counter.
Set and refer to the high-speed
counter (group 5/I6) near device
allocation.
Indirectly M8045 High-speed Counter (X5-X7) Gate Input
Indirectly M8046 High-speed Counter (X5-X7) Reset Input
- M8047 Reserved
No M8050 Modem Mode (Originate): Initialization String Start
Modem mode is not supported
and cannot be used.
No M8051 Modem Mode (Originate): ATZ Start
No M8052 Modem Mode (Originate): Dialing Start
No M8053 Modem Mode (Disconnect): Disconnect Line Start
No M8054 Modem Mode (General Command): AT Command Start
No M8055 Modem Mode (Answer): Initialization String Start
No M8056 Modem Mode (Answer): ATZ Start
No M8057 Modem Mode AT Command Execution
No M8060 Modem Mode (Originate): Initialization String Completion
No M8061 Modem Mode (Originate): ATZ Completion
No M8062 Modem Mode (Originate): Dialing Completion
No M8063 Modem Mode (Disconnect): Disconnect Line Completion
No M8064
Modem Mode (General Command): AT Command
Completion
No M8065 Modem Mode (Answer): Initialization String Completion
No M8066 Modem Mode (Answer): ATZ Completion
No M8067 Modem Mode Operational State
No M8070 Modem Mode (Originate): Initialization String Failure
No M8071 Modem Mode (Originate): ATZ Failure
No M8072 Modem Mode (Originate): Dialing Failure
No M8073 Modem Mode (Disconnect): Disconnect Line Failure
No M8074 Modem Mode (General Command): AT Command Failure
No M8075 Modem Mode (Answer): Initialization String Failure
No M8076 Modem Mode (Answer): ATZ Failure
No M8077 Modem Mode Line Connection Status
Yes M8080
Data Link Slave Station 1 Communication Completion Relay
Data Link Communication Completion Relay
Yes M8081 Data Link Slave Station 2 Communication Completion Relay
Yes M8082 Data Link Slave Station 3 Communication Completion Relay
Yes M8083 Data Link Slave Station 4 Communication Completion Relay
Yes M8084 Data Link Slave Station 5 Communication Completion Relay
Yes M8085 Data Link Slave Station 6 Communication Completion Relay
Yes M8086 Data Link Slave Station 7 Communication Completion Relay
Yes M8087 Data Link Slave Station 8 Communication Completion Relay
Yes M8090 Data Link Slave Station 9 Communication Completion Relay
Yes M8091 Data Link Slave Station 10 Communication Completion Relay
Yes M8092 Data Link Slave Station 11 Communication Completion Relay
Compatibility table (FC4A/5A series -> FC6A series)
36. 36
Replaceability
Special
internal
relay
FC4A/5A series specifications FC6A series specifications
Yes M8093 Data Link Slave Station 12 Communication Completion Relay
Yes M8094 Data Link Slave Station 13 Communication Completion Relay
Yes M8095 Data Link Slave Station 14 Communication Completion Relay
Yes M8096 Data Link Slave Station 15 Communication Completion Relay
Yes M8097 Data Link Slave Station 16 Communication Completion Relay
Yes M8100 Data Link Slave Station 17 Communication Completion Relay
Yes M8101 Data Link Slave Station 18 Communication Completion Relay
Yes M8102 Data Link Slave Station 19 Communication Completion Relay
Yes M8103 Data Link Slave Station 20 Communication Completion Relay
Yes M8104 Data Link Slave Station 21 Communication Completion Relay
Yes M8105 Data Link Slave Station 22 Communication Completion Relay
Yes M8106 Data Link Slave Station 23 Communication Completion Relay
Yes M8107 Data Link Slave Station 24 Communication Completion Relay
Yes M8110 Data Link Slave Station 25 Communication Completion Relay
Yes M8111 Data Link Slave Station 26 Communication Completion Relay
Yes M8112 Data Link Slave Station 27 Communication Completion Relay
Yes M8113 Data Link Slave Station 28 Communication Completion Relay
Yes M8114 Data Link Slave Station 29 Communication Completion Relay
Yes M8115 Data Link Slave Station 30 Communication Completion Relay
Yes M8116 Data Link Slave Station 31 Communication Completion Relay
Yes M8117 Data Link All Slave Station Communication Completion Relay
Yes M8120 Initialize Pulse
Yes M8121 1-sec Clock
Yes M8122 100-ms Clock
Yes M8123 10-ms Clock
Yes M8124 Timer/Counter Preset Value Changed
Yes M8125 In-operation Output
Yes M8126 Run-time Program Download Completion
- M8127 Reserved
Indirectly M8130
High-speed Counter (X0-X2)
Preset/Reset Status
There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 1/I0) near device allocation.
Indirectly M8131
High-speed Counter (X0-X2) Current Value Overflow or
High-speed Counter (X0-X2) Comparison ON Status
Indirectly M8132 High-speed Counter (X0-X2) Current Value Underflow
Indirectly M8133 High-speed Counter (X3) Comparison ON Status
There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 3/I3) near device allocation.
Indirectly M8134 High-speed Counter (X4) Comparison ON Status
There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 4/I4) near device allocation.
Indirectly M8135
High-speed Counter (X5-X7)
Preset/Reset Status
There is no compatibility with the
high-speed counter.
Set and refer to the high-speed counter
(group 5/I6) near device allocation.
Indirectly M8136
High-speed Counter (X5-X7) Current Value Overflow or
High-speed Counter (X5-X7) Comparison ON Status
Indirectly M8137 High-speed Counter (X5-X7) Current Value Underflow
There is no compatibility with the
high-speed counter. Set and refer to the
high-speed counter (group 5/I6) near device
allocation. “High-speed Counter (Group
5/I6) Underflow” is defined in M8164.
M8137 is defined as “Interrupt Input I0
Status (Group 1/I0).”
Compatibility table (FC4A/5A series -> FC6A series)
37. 37
Replaceability
Special
internal
relay
FC4A/5A series specifications FC6A series specifications
Indirectly M8140 Interrupt Input X2 Status It is changed to Interrupt Input I1 Status.
Indirectly M8141 Interrupt Input X3 Status It is changed to Interrupt Input I3 Status.
Indirectly M8142 Interrupt Input X4 Status It is changed to Interrupt Input I4 Status.
Indirectly M8143 Interrupt Input X5 Status It is changed to Interrupt Input I6 Status.
Yes M8144 Timer Interrupt Status
No M8145
User Communication Receive Instruction
Cancel Flag (Port 4)
The CPU module supports only ports 1 to 3. Port
4 and later are not supported and cannot be used.
No M8146
User Communication Receive Instruction
Cancel Flag (Port 5)
No M8147
User Communication Receive Instruction
Cancel Flag (Port 6)
Yes M8150 Comparison Result Greater Than
Yes M8151 Comparison Result Less Than
Yes M8152 Comparison Result Equal To
- M8153 Reserved It is Catch Input ON/OFF Status for Group 1/I0.
Indirectly M8154 Catch Input I2 ON/OFF Status Make the setting by replacing it with Group 2/I1.
Indirectly M8155 Catch Input I3 ON/OFF Status Make the setting by replacing it with Group 3/I3.
Indirectly M8156 Catch Input I4 ON/OFF Status Make the setting by replacing it with Group 4/I4.
Indirectly M8157 Catch Input I5 ON/OFF Status Make the setting by replacing it with Group 5/I6.
- M8160 Reserved
Indirectly M8161
High-speed Counter (X0-X2) Current Value
Overflow
There is no compatibility with the high-speed
counter.
Set and refer to the high-speed counter (group
1/I0) near device allocation.
Indirectly M8162
High-speed Counter (X0-X2) Current Value
Underflow
Indirectly M8163
High-speed Counter (X5-X7) Current Value
Overflow
There is no compatibility with the high-speed
counter.
Set and refer to the high-speed counter (group
5/I6) near device allocation.
Indirectly M8164
High-speed Counter (X5-X7) Current Value
Underflow
-
M8165 to
M8167
Reserved
No M8170
User Communication Receive Instruction
Cancel Flag
(Port 7)
The CPU module supports only ports 1 to 3. Port
4 and later are not supported and cannot be used.
Indirectly M8171
User Communication Receive Instruction
Cancel Flag
(Client 1)
There is no compatibility. Make the settings for
connection 1 to 8 (commonly used for the
server/client) of the CPU module, and refer to the
corresponding User Communication Receive
Instruction Cancel Flag (M8200 to M8207).
Special internal relays are defined as follows.
M8171: Reserved
M8172 to M8175: Transistor Source Output
Overcurrent Detection
Indirectly M8172
User Communication Receive Instruction
Cancel Flag
(Client 2)
Indirectly M8173
User Communication Receive Instruction
Cancel Flag
(Client 3)
-
M8174 to
M8187
Reserved
Yes M8190 IP Address Change Flag
Indirectly M8191 SNTP Calendar/Clock Data Write Flag
M8191 is defined as “SNTP Acquisition Flag,” and
operation specifications are different from those
for the FC5A series. Time setting will be
performed only once when the M8191 status is
changed from OFF to ON. To perform time setting
periodically, set the automatic acquisition cycle in
the network setting for the function setting.
Indirectly M8192
Interrupt Input 1 Edge (ON: Rising, OFF:
Falling)
Make the setting by replacing it with Group 1/I0.
Indirectly M8193
Interrupt Input 2 Edge (ON: Rising, OFF:
Falling)
Make the setting by replacing it with Group 3/I3.
Indirectly M8194
Interrupt Input 3 Edge (ON: Rising, OFF:
Falling)
Make the setting by replacing it with Group 4/I4.
Indirectly M8195
Interrupt Input 4 Edge (ON: Rising, OFF:
Falling)
Make the setting by replacing it with Group 5/I6.
Compatibility table (FC4A/5A series -> FC6A series)
38. 38
Replaceability
Special
internal relay
FC4A/5A series specifications FC6A series specifications
No M8196
Transmission Mail Server Setting
Initialize
Set M8211. M8196 is defined as “Interrupt Input
I7 Edge.”
- M8197 Reserved M8197 is defined as “Interrupt Input I1 Edge.”
Indirectly
M8200 to
M8207
User Communication Receive Instruction
Cancel Flag
(Servers 1 to 8)
There is no compatibility. Make the settings for
connection 1 to 8 (commonly used for the
server/client) of the CPU module, and refer to
the corresponding User Communication
Receive Instruction Cancel Flag (M8200 to
M8207).
Special internal relays are defined as follows.
M8200 to M8207:
User Communication Receive Instruction
Cancel Flag
(Connection 1 to 8)
-
M8210 to
M8211
Reserved
Indirectly
M8212 to
M8214
Maintenance Communication Server 1 to
3 Status
There is no compatibility. Make the settings for
connection 1 to 8 (commonly used for the
server/client) of the CPU module, and refer to
the corresponding Connection Status (M8212
to M8221) and User Communication
Connection Disconnect Flag (M8222 to
M8231).
Special internal relays are defined as follows.
M8212 to M8221:
Connection Status (Connection 1 to 8)
M8222 to M8231:
Disconnect User Communication
Connection (Connection 1 to 8)
M8232:
Refer to HMI module connection
information.
Connection Status
Indirectly
M8215 to
M8217
Client Connection 1 to 3 Status
Indirectly
M8220 to
M8227
Server Connection 1 to 8 Status
Indirectly
M8230 to
M8232
Client Connection 1 to 3 Disconnect Flag
-
M833 to
M8317
Reserved
Compatibility table (FC4A/5A series -> FC6A series)
39. 39
Special data registers
Replaceability
Special
data
register
FC4A/5A series specifications FC6A series specifications
Yes D8000 CPU Module System (Quantity of Inputs)
Yes D8001 CPU Module System (Quantity of Outputs)
Yes D8002 CPU Module Type Information
No D8003 Memory Cartridge Information
It cannot be used because there is no memory
cartridge. Read out a file in an SD memory
card using WindLDR.
- D8004 Reserved
Yes D8005 General Error Code
Yes D8006 User Program Execution Error Code
No D8007 Communication Mode Switching (Port 1 and 2)
The communication mode switching function
cannot be used. To use maintenance
communication, use the USB port.
Yes D8008 Year (Current Data) Read only
Yes D8009 Month (Current Data) Read only
Yes D8010 Day (Current Data) Read only
Yes D8011 Day of Week (Current Data) Read only
Yes D8012 Hour (Current Data) Read only
Yes D8013 Minute (Current Data) Read only
Yes D8014 Second (Current Data) Read only
Yes D8015 Year (New Data) Write only
Yes D8016 Month (New Data) Write only
Yes D8017 Day (New Data) Write only
Yes D8018 Day of Week (New Data) Write only
Yes D8019 Hour (New Data) Write only
Yes D8020 Minute (New Data) Write only
Yes D8021 Second (New Data) Write only
Yes D8022 Constant Scan Time Preset Value
Yes D8023 Scan Time Current Value (ms)
Yes D8024 Scan Time Maximum Value (ms)
Yes D8025 Scan Time Minimum Value (ms)
Indirectly D8026
Communication Mode Information (Port 1
through Port 7)
Communication mode is defined differently.
Make corrections according to the definition
for the FC6A series.
Indirectly D8027 Port 1 Communication Network Number Special data register allocation is different.
Only when a data register is specified for the
slave number in the communication port
setting, the slave number can be changed in
D8100, D8102, and D8103.
Indirectly D8028 Port 2 Communication Network Number
Yes D8029 System Program Version
Indirectly D8030 Communication Adapter Information Change the setting according to the option for
the FC6A series.Indirectly D8031 Optional Cartridge Information
Indirectly D8032
Interrupt Input Jump Destination Label No.
(X2)
Make the setting by replacing it with Group
2/I1.
Indirectly D8033
Interrupt Input Jump Destination Label No.
(X3)
Make the setting by replacing it with Group
3/I3.
Indirectly D8034
Interrupt Input Jump Destination Label No.
(X4)
Make the setting by replacing it with Group
4/I4.
Indirectly D8035
Interrupt Input Jump Destination Label No.
(X5)
Make the setting by replacing it with Group
5/I6.
Yes D8036 Timer Interrupt Jump Destination Label No.
Yes D8037 Quantity of Expansion I/O Modules
- D8038 Reserved
- D8039 Reserved
Compatibility table (FC4A/5A series -> FC6A series)
40. 40
Replaceability
Special
data
register
FC4A/5A series specifications FC6A series specifications
No D8040
Data Link Slave Station
Number/
Modbus Slave Number
Port 3 The CPU module supports ports 1 to 3. Port 4 and
later are not provided and they cannot be used.
D8038 to D8051 are defined as reserved.
No D8041 Port 4
No D8042 Port 5
No D8043 Port 6
No D8044 Port 7
Indirectly D8045 High-speed Counter (X0-X2) Current Value Make the setting while referring to the current
value and the preset value for the high-speed
counter (group 1/I0) in D8210 to D8213.
Indirectly D8046
High-speed Counter (X0-X2) Reset Value
or Preset Value
Indirectly D8047 High-speed Counter (X3) Current Value Make the setting while referring to the current
value and the preset value for the high-speed
counter (group 3/I3) in D8218 to D8221.
Indirectly D8048 High-speed Counter (X3) Reset Value
Indirectly D8049 High-speed Counter (X4) Current Value Make the setting while referring to the current
value and the preset value for the high-speed
counter (group 4/I4) in D8222 to D8225.
Indirectly D8050 High-speed Counter (X4) Reset Value
Indirectly D8051 High-speed Counter (X5-X7) Current Value Make the setting while referring to the current
value and the preset value for the high-speed
counter (group 5/I6) in D8226 to D8229.
D8052 is defined as J1939 Communication Error
Code.
Indirectly D8052
High-speed Counter (X5-X7) Reset Value
or Preset Value
No D8053 Modbus slave communication error code
Set an arbitrary data register as the error status in
the setting window for the Modbus master request
table.
D8053 to D8055 are defined as reserved.
No D8054 Modbus slave communication transmission
wait time for ASCII
Make the setting in the communication setting for
the Modbus master request table.
No D8055
Current Pulse Frequency of PULS1 or
RAMP1 (Y0)
It cannot be used because the frequency band
that can be output is different.
No D8056
Current Pulse Frequency of PULS2 or
RAMP1 (Y1)
It cannot be used because the frequency band
that can be output is different.
D8056 is defined as Battery Voltage.
Yes D8057 Analog Potentiometer 1 Value
No D8058
Analog Potentiometer 2 Value (All-in-One
type CPU)/Analog Voltage Input (Slim type
CPU modules)
Analog Potentiometer 2 is not supported and
cannot be used.
D8058 is defined as Built-in Analog Input (AI1).
No D8059
Current Pulse Frequency of PULS3 or
RAMP2 (Y2)
It cannot be used because the frequency band
that can be output is different.
D8059 is defined as Analog Input Status AI0.
Indirectly
D8060
D8061
Slim type
D8060, D8061: Frequency Measurement
ValueX1
All-in-One type
D8060: Frequency Measurement Value
X1, D8061: Reserved
Refer to the frequency measurement current
value for the high-speed counter (group 1/I0) in
D8210 to D8211.
D8060 is defined as Analog Input Status AI1.
Indirectly
D8062
D8063
Slim type
D8062, D8063: Frequency Measurement
Value X3
All-in-One type
D8062: Frequency Measurement Value
X3, D8063: Reserved
Refer to the frequency measurement current
value for the high-speed counter (group 3/I3) in
D8218 to D8219.
Indirectly
D8064
D8065
Slim type
D8064, D8065: Frequency Measurement
Value X4
All-in-One type
D8064: Frequency Measurement Value
X4, D8065: Reserved
Refer to the frequency measurement current
value for the high-speed counter (group 4/I4) in
D8222 to D8223.
Indirectly
D8066
D8067
Slim type
D8066, D8067: Frequency Measurement
Value X5
All-in-One type
D8066: Frequency Measurement Value
X5, D8067: Reserved
Refer to the frequency measurement current
value for the high-speed counter (group 5/I6) in
D8226 to D8227.
D8067 is defined as Backlight ON Time
No D8068 HMI Module Initial Screen Selection
It is not supported and cannot be used. Use the
MSG instruction.
Compatibility table (FC4A/5Aseries->FC6Aseries)
41. 41
Replaceability
Special
data
register
FC4A/5A series specifications FC6A series specifications
Indirectly D8069
Slave Station 1 Communication Error (at Master
Station)
Slave Station Communication Error (at Slave
Station)
Error station number and error code (at Modbus
Master)
When the data link master station and
data link slave station are used, they can
be used as with the FC5A series
All-in-One type.
When Modbus master communication is
used, set the error status into an arbitrary
data register in the setting screen for the
Modbus request table.
Indirectly D8070
Slave Station 2-31 Communication Error (at Master
Station)
Error station number and error code (at Modbus
Master)
Indirectly D8071
Indirectly D8072
Indirectly D8073
Indirectly D8074
Indirectly D8075
Indirectly D8076
Indirectly D8077
Indirectly D8078
Indirectly D8079
Indirectly D8080
Indirectly D8081
Indirectly D8082
Indirectly D8083
Indirectly D8084
Indirectly D8085
Indirectly D8086
Indirectly D8087
Indirectly D8088
Indirectly D8089
Indirectly D8090
Indirectly D8091
Indirectly D8092
Indirectly D8093
Indirectly D8094
Indirectly D8095
Indirectly D8096
Indirectly D8097
Indirectly D8098
Indirectly D8099
Indirectly D8100
Data Link Slave Station Number (Port 2)/Modbus
Slave Number (Port 2)
D8100 is defined as Slave Number (Port
1). When port 1 is maintenance
communication, Modbus RTU slave, or
data link slave, the slave number can be
changed.
No D8101 Data Link Transmit Wait Time (ms)
It is intended for connection with FA-3S.
It is not supported this time and cannot
be used. D8101 is defined as reserved.
Compatibility table (FC4A/5A series -> FC6A series)
42. 42
Replaceability
Special data
register
FC4A/5A series specifications FC6A series specifications
- D8102 Reserved
D8102 is defined as Slave Number (Port 2).
When port 2 is maintenance communication, Modbus
RTU slave, or data link slave, the slave number can be
changed.
No D8103 Online Mode Protocol Selection
Modem mode is not supported.
D8103 is defined as Slave Number (Port 3). When port
3 is maintenance communication, Modbus RTU slave,
or data link slave, the slave number can be changed.
Indirectly D8104
RS232C
Communication
board
Control Signal
Status
The port number is defined differently.
Set and refer to the number according to the
communication port to be used.
Indirectly D8105
DR Input
Control Signal
Option
Indirectly D8106
ER Output
Control Signal
Option
- D8107 Reserved
- D8108 Reserved
No D8109 Retry Cycles
Modem mode is not supported and cannot be used.
D8109 to D8111 are defined as reserved.
No D8110 Retry Interval
No D8111 Modem Mode Status
- D8112 Reserved
- D8113 Reserved
- D8114 Reserved
No
D8115 to
D8129
AT Command Result Code
Modem mode is not supported and cannot be used.
Special data registers are defined as follows.
D8115 to D8119: Reserved
D8120 to D8121: HMI Module Information
D8122 to D8127: Cartridge Slot 1-3 Information
D8128 to D8169: Reserved
D8170 to D8181: Information related to analog
cartridge I/O
D8182 to D8191: Reserved
D8192 to D8197: High-speed Counter (Group
2/I1)
D8198 to D8203: High-speed Counter (Group
6/I7)
No
D8130 to
D8144
AT Command String
No
D8145 to
D8169
Initialization String
No
D8170 to
D8199
Modem dialing command
-
D8200 to
D8203
Reserved
No D8204
RS232C Control Signal Status
(Port 7)
The CPU module supports only ports 1 to 3. Port 4 and
later are not supported and cannot be used.
D8204 to D8209 are defined as reserved.
No D8205
RS232C DR Input Control Signal
Option (Port 7)
No D8206
RS232C ER Output Control
Signal Option (Port 7)
-
D8207 to
D8209
Reserved
Indirectly D8210 High-speed Counter (X0-X2)
Current Value
There is no compatibility with the high-speed counter.
Set and refer to the high-speed counter (group 1/I0)
near device allocation.
Indirectly D8211
Indirectly D8212 High-speed Counter (X0-X2)
Preset Value 1Indirectly D8213
Indirectly D8214 High-speed Counter (X0-X2)
Preset Value 2Indirectly D8215
Indirectly D8216 High-speed Counter (X0-X2)
Reset ValueIndirectly D8217
Compatibility table (FC4A/5A series -> FC6A series)
43. 43
Replaceability
Special data
register
FC4A/5A series specifications FC6A series specifications
Indirectly D8218
High-speed Counter (X3) Current Value There is no compatibility with the high-speed
counter.
Set and refer to the high-speed counter
(group 3/I3) near device allocation.
Indirectly D8219
Indirectly D8220
High-speed Counter (X3) Reset Value
Indirectly D8221
Indirectly D8222
High-speed Counter (X4) Current Value There is no compatibility with the high-speed
counter.
Set and refer to the high-speed counter
(group 4/I4) near device allocation.
Indirectly D8223
Indirectly D8224
High-speed Counter (X4) Reset Value
Indirectly D8225
Indirectly D8226
High-speed Counter (X5-X7) Current Value
There is no compatibility with the high-speed
counter.
Set and refer to the high-speed counter
(group 5/I6) near device allocation.
Indirectly D8227
Indirectly D8228
High-speed Counter (X5-X7) Reset Value 1
Indirectly D8229
Indirectly D8230
High-speed Counter (X5-X7) Reset Value 2
Indirectly D8231
Indirectly D8232
High-speed Counter (X5-X7) Preset Value
Indirectly D8233
-
D8234 to
D8251
Reserved
No D8252
Expansion Interface Module I/O Refresh
Time (x100 µs)
It is not supported and cannot be used.
Expansion module I/O refresh is performed
by the CPU module. It is not performed by
the expansion interface module.
D8252 is defined as reserved.
-
D8253 to
D8277
Reserved
No D8278
Communication Mode Information (Client
Connection)
There is no compatibility. D8278 is defined
as “Communication Mode Information
(Client Connection) Connection 1 to 4.”
No D8279
Communication Mode Information (Server
Connection)
There is no compatibility. D8279 is defined
as “Communication Mode Information
(Client Connection) Connection 5 to 8.”
-
D8280 to
D8301
Reserved
No D8302 Memory Cartridge Capacity
It is not supported and cannot be used. For
SD memory card capacity, refer to D8250.
D8302 is defined as reserved.
No D8303 IP Address Switching
It is not supported and cannot be used.
Make the selection and setting in the
network setting for the function setting.
Yes
D8304 to
D8307
IP Address
(New Data) Write only
Yes
D8308 to
D8311
Subnet Mask
(New Data) Write only
Yes
D8312 to
D8315
Default Gateway
(New Data) Write only
Yes
D8316 to
D8319
Preferred DNS Server
(New Data) Write only
Yes
D8320 to
D8323
Alternate DNS Server
(New Data) Write only
Yes
D8324 to
D8329
MAC Address
Yes
D8330 to
D8333
IP Address (Current Data) Read only
Compatibility table (FC4A/5A series -> FC6A series)
44. 44
Replaceability
Special
data
register
FC4A/5A series specifications FC6A series specifications
Yes
D8334 to
D8337
Subnet Mask (Current Data) Read only
Yes
D8338 to
D8341
Default Gateway (Current Data) Read
only
Yes
D8342 to
D8345
Preferred DNS Server (Current Data)
Read only
Yes
D8346 to
D8349
Alternate DNS Server (Current Data)
Read only
Indirectly
D8350 to
D8353
Maintenance Communication Server 1
Connected IP Address
There is no compatibility. Make the settings for
connection 1 to 8 (commonly used for the
server/client) of the CPU module, and refer to the
corresponding connected IP address (D8350 to
D8381).
Special data registers are defined as follows.
D8350 to D8353: Connection 1 Connected IP
Address
D8354 to D8357: Connection 2 Connected IP
Address
D8358 to D8361: Connection 3 Connected IP
Address
D8362 to D8365: Connection 4 Connected IP
Address
D8366 to D8369: Connection 5 Connected IP
Address
D8370 to D8373: Connection 6 Connected IP
Address
D8374 to D8377: Connection 7 Connected IP
Address
D8378 to D8381: Connection 8 Connected IP
Address
Indirectly
D8354 to
D8357
Maintenance Communication Server 2
Connected IP Address
Indirectly
D8358 to
D8361
Maintenance Communication Server 3
Connected IP Address
Indirectly
D8362 to
D8365
Server Connection 1 Connected IP
Address
Indirectly
D8366 to
D8369
Server Connection 2 Connected IP
Address
Indirectly
D8370 to
D8373
Server Connection 3 Connected IP
Address
Indirectly
D8374 to
D8377
Server Connection 4 Connected IP
Address
Indirectly
D8378 to
D8381
Server Connection 5 Connected IP
Address
Indirectly
D8382 to
D8385
Server Connection 6 Connected IP
Address
There is no compatibility. Make the settings for
connection 1 to 8 (commonly used for the
server/client) of the CPU module, and refer to the
corresponding connected IP address (D8350 to
D8381).
Special data registers are defined as follows.
D8382 to D8387: HMI Module MAC Address
(Current Value Read-only)
D8388 to D8391: HMI Module IP Address
(Current Value Read-only)
D8392 to D8395: HMI Module Subnet Mask
(Current Value Read-only)
D8396 to D8399: HMI Module Default Gateway
(Current Value Read-only)
D8400 to D8403: HMI Module Preferred DNS
Server (Current Value
Read-only)
D8404 to D8407: HMI Module Alternate DNS
Server (Current Value
Read-only)
D8408 to D8412: Reserved
Indirectly
D8386 to
D8389
Server Connection 7 Connected IP
Address
Indirectly
D8390 to
D8393
Server Connection 8 Connected IP
Address
-
D8406 to
D8412
Reserved
Compatibility table (FC4A/5A series -> FC6A series)
45. 45
Replaceability
Special
data
register
FC4A/5A series specifications FC6A series specifications
Yes D8413 Time Zone Offset
No D8414 Year (Obtained from SNTP) It is not supported and cannot be used. The CPU
module uses the built-in clock, and a simple clock
function is not required. Also, information obtained
from SNTP will be automatically reflected to the
built-in clock.
Special data registers are defined as follows.
D8414: SNTP Operation Status
D8415: SNTP Access Elapsed Time
D8416 to D8420: Reserved
No D8415 Month (Obtained from SNTP)
No D8416 Day (Obtained from SNTP)
No D8417 Day of Week (Obtained from SNTP)
No D8418 Hour (Obtained from SNTP)
No D8419 Minute (Obtained from SNTP)
No D8420 Second (Obtained from SNTP)
No D8421
Maintenance Communication Server 1
Port Number of Client
Connection port numbers are not supported and
cannot be used.
Special data registers are defined as follows.
D8421 to D8348: Reserved
D8429 to D8434: Refer to HMI module
connection information.
D8435 to D8436: Reserved
D8437 to D8440: HMI Module IP Address
(Write-only)
D8441 to D8444: HMI Module Subnet Mask
(Write-only)
D8445 to D8448: HMI Module Default Gateway
(Write-only)
D8449 to D8452: HMI Module Preferred DNS
Server (Write-only)
D8453 to D8456: HMI Module Alternate DNS
Server (Write-only)
No D8422
Maintenance Communication Server 2
Port Number of Client
No D8423
Maintenance Communication Server 3
Port Number of Client
No D8424
Server Connection 1 Port Number of
Client
No D8425
Server Connection 2 Port Number of
Client
No D8426
Server Connection 3 Port Number of
Client
No D8427
Server Connection 4 Port Number of
Client
No D8428
Server Connection 5 Port Number of
Client
No D8429
Server Connection 6 Port Number of
Client
No D8430
Server Connection 7 Port Number of
Client
No D8431
Server Connection 8 Port Number of
Client
-
D8432 to
D8456
Reserved
Yes D8457 EMAIL Error Information
-
D8458 to
D8499
Reserved
Compatibility table (FC4A/5A series -> FC6A series)
46. 46
Programming software
PLC programming software “WindLDR (Ver.7.0 or later)” included in our system integration software
“Automation Organizer” (series No.: SW1A-W1C) is used for the FT1A series Pro/Lite as with the
FC4A/FC5A series.
The latest update file is published on our website. It is recommended to use the latest version of
“Automation Organizer” for program conversion.
http://us.idec.com/ProductSupport/Software.aspx
Program conversion for FT1A series Pro/Lite
Some of the FC4A/5A series programs are incompatible with the FT1A series Pro/Lite programs.
Thus, it is impossible to perform automatic conversion of all programs completely. Program
conversion should be performed according to the WindLDR model setting. By changing the model,
instructions that can be replaced automatically will be converted and instructions that need to be
replaced manually or cannot be replaced will remain unconverted.
All function settings will be lost at the time of model change. It is necessary to reset them after
model change.
For details about the compatibility with each item of I/O numbers and special devices, refer to
[Compatibility table (FC4A/5A -> FT1A) in page 50].
Program uploading
If the ladder program file for the FC4A/5A series does not remain,
connect the main body of the FC4A/5A series to a PC (RS232
interface) via a PC interface cable (FC2A-KC4C) to upload (read
out) the program. The procedure is as follows.
Click [Upload] in the [Online] tab of WindLDR.
The upload window will appear. Click [OK].
FC2A-KC4C
Click [Upload].
Click [OK].
Program conversion (FC4A/5A series -> FT1A series)
47. 47
Conversion procedure
Open the program for the FC4A/5A series using WindLDR.
Click the [PLC Type] icon in the [Configuration] tab.
In the displayed window, select the CPU module to be used after conversion and then click
[OK].
Conversion report
When conversion has been performed according to the procedure, the conversion report will be
output in the information window as shown in the example below.
When the mouse cursor is put on each item of the conversion report in the information window to
select the item, the cursor in the ladder program field will also move to the related ladder part in
conjunction.
Click [PLC Type].
Select a CPU module and
then click [OK].
The cursor moves in
conjunction.
Program conversion (FC4A/5A series -> FT1A series)
48. 48
Batch conversion of I/O numbers
Consecutive I/O numbers can be converted at a time. Use this function when I/Os of the FC6A
series CPU module are not used or when reserved numbers should be skipped.
1. Click [Replace] in the [Home] tab, and further, select [Replace].
2. In the displayed window, enter the I/O numbers before and after conversion in [Device] and the
I/O points to be converted in [Points to Replace]. If comments should also be moved, mark the
checkbox for [Replace comment].
3. Click [Replace].
Click [Replace] and select
[Replace] further.
Enter the I/O numbers
before and after conversion
and the number of points to
be converted.
Mark the checkbox for
[Move comments] as
necessary.
Click [Replace].
Program conversion (FC4A/5A series -> FT1A series)
49. 49
4. The cursor will move to the I/O to be converted, and the confirmation window will appear. To
convert while confirming I/Os one by one, click [Yes]. To convert the remaining I/Os at a time
without confirming them, click [Yes to all].
The cursor moves to
the I/O to be converted.
Click [Yes] or [Yes to
all] in the displayed
window.
Program conversion (FC4A/5A series -> FT1A series)
50. 50
Function settings
The available options for replacing of all setting items are shown in the table below.
All function settings will be lost at the time of model change from the FC4A/5A series to the FT1A
series. It is necessary to reset them after model change.
Yes: Setting that can be replaced
Indirectly: Setting of which functions cannot be partially replaced
No: Setting that cannot be replaced
Replaceability Function setting for FC4A/5A series FT1A series specifications
Yes Operation/stop control
Inputs that can be specified by stop input and reset input will
be within the input range for the FT1A series.
Yes Memory backup
Devices that can be specified will be within the device range
for the FT1A series.
Indirectly
Special input
High-speed counter It can be selected from among six high-speed counter groups.
Yes Catch input They are automatically replaced with the same group numbers.
However, the input terminal numbers are different.Yes Interrupt input
Indirectly
Frequency
measurement
It can be selected easily using the “Frequency measurement”
function.
Yes Input filter Filter specification can be performed in a single point unit.
Yes Timer interruption
Indirectly/No*1 Communication port setting
• Some of the communication modes cannot be replaced. (*1)
• The number of serial communication ports is two at the
maximum.
• There is no specification for communication switching input.
No Communication refresh for ports 3 to 7
No setting is required because communication refresh is
performed regularly.
No Communication option
It is not supported and cannot be used. Specify a constant as
the slave number for each communication mode setting, or
specify or select using the data resister.
No Key matrix Not supported. To expand I/Os, use the remote I/O function.
No Clock cartridge
A clock is built in. Because the correction value is written at the
time of shipment, no setting is required.
Yes Memory cartridge
No Expansion modules
• Expansion modules are not supported.
• There is no function to substitute the AS-Interface module.
Yes Device setting
Yes Program protection
The old password can also be used if the program protection is
not changed.
No Self-diagnosis
The RUN LED blinking setting is not supported and cannot be
used.
*1 The following communication modes cannot be replaced:
Modem communication, Modbus ASCII master/slave, Modbus TCP master/slave using
FC4A-SX5ES1J, data link slave, data link master
Compatibility table (FC4A/5A series -> FT1A series)
51. 51
Basic instructions
The available basic instructions for replacing are shown in the table below.
Yes: Instruction that can be replaced automatically
No: Instruction that cannot be replaced
Replaceability
Instruction for FC4A/5A
series
FT1A series specifications
Yes Normally open contact
Yes Normally closed contact
Yes OUT
Yes OUTN
Yes SET
Yes RST
Yes AND
Yes ANDN
Yes OR
Yes ORN
Yes AND•LOD
Yes OR•LOD
Yes BPS
Yes BRD
Yes BPP
Yes TML
Yes TIM
Yes TIMH
Yes TMS
Yes CNT
Yes CDP
Yes CUD
Yes CC=
Yes CC>=
Yes DC=
Yes DC>=
Yes SFR
Yes SFRN
Yes SOTU
Yes SOTD
Yes JMP
Yes JEND
Yes MCS
Yes MCR
Yes END
Compatibility table (FC4A/5A series -> FT1A series)
52. 52
Advanced instructions
The available advanced instructions for replacing are shown in the table below.
Yes: Compatible instruction that can be replaced automatically
Indirectly: Instruction that needs to be replaced manually
No: Instruction that cannot be replaced
Replaceability Instruction for FC4A/5A series FT1A series specifications
Yes MOV, MOVN
Yes IMOV, IMOVN
Yes IBMV, IBMVN
Yes BMOV
Yes NSET, NRS
Yes XCHG
Yes TCCST
Yes CMP* (*: =, <>, <, <=, >, >=)
Yes ICMP >=
Yes LC
Yes ADD, SUB
Yes MUL
Yes DIV
Yes ROOT
Yes INC, DEC
Yes SUM
No RNDM It is not supported by the FT1A series and cannot be used.
Yes ANDW, ORW, XORW
Yes SFTL, SFTR
Yes ROTL, ROTR
Yes BCDLS
Yes WSFT
Yes HTOB, ATOB
Yes BTOH, ATOH
Yes HTOA, BTOA
Yes ENCO, DECO
Yes BCNT
Yes ALT
Yes CVDT
Yes DTDV
Yes DTCB
Yes SWAP
No DISP It is not supported by the FT1A series and cannot be used.
No DGRD It is not supported by the FT1A series and cannot be used.
No WKTBL It is not supported by the FT1A series and cannot be used.
Use the WEEK instruction/YERA instruction.No WKTIM
Compatibility table (FC4A/5Aseries->FT1Aseries)
53. 53
Replaceability Instruction for FC4A/FC5A series FT1A series specifications
Indirectly TXD, RXD
To perform serial communication in the FT1A series, a
communication cartridge (FT1A-PC1/-PC2/-PC3) is required.
Specify the port number appropriate for the communication port
to be used.
Yes XYFS, CVXTY, CVYTX
Yes AVRG
No PID It is not supported by the FT1A series and cannot be used.
Yes DTML, DTIM, DTMH, DTMS
Yes TTIM
Yes LABEL
Yes LJMP
Yes LCAL
Yes LRET
Yes DJNZ
Yes DI, EI
Yes IOREF
Yes HSCRF
Yes FRQRF
No COMRF
It is not supported by the FT1A series and cannot be used.
It is unnecessary because communication port refresh is
performed regularly.
No RUNA, STPA
It is not supported by the FT1A series and cannot be used.
Expansion modules cannot be connected.
Yes RAD
Yes DEG
Yes SIN, COS, TAN
Yes ASIN, ACOS, ATAN
Yes LOG10
Yes EXP
Yes LOGE
Yes POW
Yes FIFOF, FIEX, FOEX
Yes NDSRC
Yes TADD, TSUB
Yes HTOS, STOH
Yes HOUR
Yes NOP
Compatibility table (FC4A/5A series -> FT1A series)
54. 54
Macro instructions
Whether macro instructions can be replaced or not is shown in the table below.
Macro instructions are not supported by the FT1A series.
No: Instruction that cannot be replaced
Replaceability Instruction for FC4A series Remarks
No MACRO
No CWWT, CWRD
No ANST
No PULSST
No PWMST
No RAMPST
No ZRNST
No PIDST
Compatibility table (FC4A/5A series -> FT1A series)
55. 55
Special devices
Whether special internal relays can be replaced or not and the corresponding numbers are shown
in the table below.
Yes: Compatible device that can be replaced
Indirectly: Device that has a compatibility function but requires re-allocation
No: Device that cannot be replaced
Special internal relay
Replaceability
Special
internal
relay
FC4A/5A series specifications FT1A series specifications
Yes M8000 Start Control
Yes M8001 1-s Clock Reset
Yes M8002 All Outputs OFF
Yes M8003 Carry (Cy) or Borrow (Bw)
Yes M8004 User Program Execution Error
No M8005 Data Link Communication Error
Data link communication is not supported.
M8005 to M8007 are defined as “Remote I/O
Slave 1-3 Communication Error”
No M8006
Data Link Communication Prohibit Flag (Master
Station)
No M8007
Data Link Communication Initialize Flag
(Master Station)
Data Link Communication Stop Flag (Slave
Station)
No M8010 Status LED
The status LED is not supported and cannot
be used.
M8010 is defined as “In daylight saving time
period.”
No M8011 HMI Write Prohibit Flag It is not supported and cannot be used.
M8011 to M8012 are defined as “reserved”No M8012 HMI Operation Prohibit Flag
Yes M8013 Calendar/Clock Data Write/Adjust Error Flag
Yes M8014 Calendar/Clock Data Read Error Flag
No M8015 Calendar/Clock Data Read Stop Flag
The CPU module uses the built-in clock,
which cannot be stopped.
M8015 is defined as “Reserved”
Yes M8016 Calendar Data Write Flag
Yes M8017 Clock Data Write Flag
Yes M8020 Calendar/Clock Data Write Flag
Yes M8021 Clock Data Adjust Flag
Indirectly M8022
User Communication Receive Instruction
Cancel Flag (Port 1)
It is port 2 for the FT1A series
Indirectly M8023
User Communication Receive Instruction
Cancel Flag (Port 2)
It is port 3 for the FT1A series
Yes M8024 BMOV/WSFT Executing Flag
Yes M8025 Maintain Outputs While CPU Stopped
Compatibility table (FC4A/5A series -> FT1A series)
56. 56
Replaceability
Special
internal
relay
FC4A/5A series specifications FT1A series specifications
No M8026
Expansion Data Register Data Writing Flag
(Preset Range 1)
The expansion data register is not
supported. Use the ROM backup function of
the data register.
Special internal relays are defined as follows
M8026: “SD Memory Card Status”
M8027: “SD Memory Card Writing Flag”
No M8027
Expansion Data Register Data Writing Flag
(Preset Range 2)
Indirectly M8030
High-speed Counter (X0-X2) Comparison Output
Reset
There is no compatibility with the high-speed
counter. Select a high-speed counter group
and make the setting.
M8030 to M8032 are defined as “High-speed
Counter (Group 1/I0)”.
Indirectly M8031 High-speed Counter (X0-X2) Gate Input
Indirectly M8032
High-speed Counter (X0-X2) Reset Input or
Preset Input
No M8033
User Communication Receive Instruction Cancel
Flag (Port 3)
Port 3 is not provided for the FT1A series.
M8033 is defined as “High-speed Counter
(Group 1/I0)”.
Indirectly M8034
High-speed Counter (X3) Comparison Output
Reset
There is no compatibility with the high-speed
counter. Select a high-speed counter group
and make the setting.
Special internal relays are defined as
follows.
M8034 to M8037: “High-speed Counter
(Group 1/I0)”
M8040 to M8044: “High-speed Counter
(Group 2/I2)”
M8045 to M8046: “High-speed Counter
(Group 3/I3)”
Indirectly M8035 High-speed Counter (X3) Gate Input
Indirectly M8036 High-speed Counter (X3) Reset Input
- M8037 Reserved
Indirectly M8040
High-speed Counter (X4) Comparison Output
Reset
Indirectly M8041 High-speed Counter (X4) Gate Input
Indirectly M8042 High-speed Counter (X4) Reset Input
- M8043 Reserved
Indirectly M8044
High-speed Counter (X5-X7) Comparison Output
Reset
Indirectly M8045 High-speed Counter (X5-X7) Gate Input
Indirectly M8046 High-speed Counter (X5-X7) Reset Input
- M8047 Reserved
No M8050
Modem
mode
[Originate]: Initialization String Start
Modem mode is not supported.
M8050 to M8054 are defined as “High-speed
Counter (Group 3/I3).”
No M8051 [Originate]: ATZ Start
No M8052 [Originate]: Dialing Start
No M8053 [Disconnect]: Disconnect Line Start
No M8054
[General Command]: AT Command
Start
No M8055 [Answer]: Initialization String Start
Modem mode is not supported.
M8055 to M8061 are defined as “High-speed
Counter (Group 4/I5).”
No M8056 [Answer]: ATZ Start
No M8057 AT Command Execution
No M8060
[Originate]: Initialization String
Completion
No M8061 [Originate]: ATZ Completion
No M8062 [Originate]: Dialing Completion
Modem mode is not supported.
M8062 to M8067 are defined as “Reserved.”
No M8063
[Disconnect]: Disconnect Line
Completion
No M8064
[General Command]: AT Command
Completion
No M8065
[Answer]: Initialization String
Completion
No M8066 [Answer]: ATZ Completion
No M8067 Modem Mode Operational State
Compatibility table (FC4A/5A series -> FT1A series)
57. 57
Replaceability
Special
internal
relay
FC4A/5A series specifications FT1A series specifications
No M8070
Modem
mode
[Originate]: Initialization String Failure Modem mode is not supported.
Special internal relays are defined as
follows.
M8070 to M8075:
“Interrupt Input Status”
M8076:
“SD Memory Card Access Stop Flag”
M8077:
“Reserved”
No M8071 [Originate]: ATZ Failure
No M8072 [Originate]: Dialing Failure
No M8073 [Disconnect]: Disconnect Line Failure
No M8074 [General Command]: AT Command Failure
No M8075 [Answer]: Initialization String Failure
No M8076 [Answer]: ATZ Fai
No M8077 Modem Mode Line Connection Status
No M8080
Data Link Slave Station 1 Communication Completion Relay
(Master Station)
Data Link Communication Completion Relay (Slave Station)
Data link communication is not
supported.
Special internal relays are defined as
follows.
M8080 to M8085:
“Interrupt Input Edge”
M8086 to M8087:
“Reserved”
M8090 to M8095:
“Catch Input ON/OFF Status”
M8096 to M8097:
“Reserved”
M8100 to M8102:
“User Communication Receive
Instruction Cancel Flag”
M8103 to M8107:
“Reserved”
M8110 to M8112:
“Connection Status”
M8113 to M8117:
“Reserved”
No M8081 Data Link Slave Station 2 Communication Completion Relay
No M8082 Data Link Slave Station 3 Communication Completion Relay
No M8083 Data Link Slave Station 4 Communication Completion Relay
No M8084 Data Link Slave Station 5 Communication Completion Relay
No M8085 Data Link Slave Station 6 Communication Completion Relay
No M8086 Data Link Slave Station 7 Communication Completion Relay
No M8087 Data Link Slave Station 8 Communication Completion Relay
No M8090 Data Link Slave Station 9 Communication Completion Relay
No M8091 Data Link Slave Station 10 Communication Completion Relay
No M8092 Data Link Slave Station 11 Communication Completion Relay
No M8093 Data Link Slave Station 12 Communication Completion Relay
No M8094 Data Link Slave Station 13 Communication Completion Relay
No M8095 Data Link Slave Station 14 Communication Completion Relay
No M8096 Data Link Slave Station 15 Communication Completion Relay
No M8097 Data Link Slave Station 16 Communication Completion Relay
No M8100 Data Link Slave Station 17 Communication Completion Relay
No M8101 Data Link Slave Station 18 Communication Completion Relay
No M8102 Data Link Slave Station 19 Communication Completion Relay
No M8103 Data Link Slave Station 20 Communication Completion Relay
No M8104 Data Link Slave Station 21 Communication Completion Relay
No M8105 Data Link Slave Station 22 Communication Completion Relay
No M8106 Data Link Slave Station 23 Communication Completion Relay
No M8107 Data Link Slave Station 24 Communication Completion Relay
No M8110 Data Link Slave Station 25 Communication Completion Relay
No M8111 Data Link Slave Station 26 Communication Completion Relay
No M8112 Data Link Slave Station 27 Communication Completion Relay
No M8113 Data Link Slave Station 28 Communication Completion Relay
No M8114 Data Link Slave Station 29 Communication Completion Relay
No M8115 Data Link Slave Station 30 Communication Completion Relay
No M8116 Data Link Slave Station 31 Communication Completion Relay
No M8117 Data Link All Slave Station Communication Completion Relay
Compatibility table (FC4A/5A series -> FT1A series)
58. 58
Replaceability
Special
internal
relay
FC4A/5A series specifications FT1A series specifications
Yes M8120 Initialize Pulse
Yes M8121 1-sec Clock
Yes M8122 100-ms Clock
Yes M8123 10-ms Clock
Yes M8124 Timer/Counter Preset Value Changed
Yes M8125 In-operation Output
No M8126 Run-time Program Download Completion
The run-time program is not supported.
M8126 is defined as “Reserved.”
- M8127 Reserved
Indirectly M8130
High-speed
Counter 1
(X0-X2)
Preset/Reset Status
There is no compatibility. Make the setting
for the high-speed counter according to the
definition for the FT1A series.
Special internal relays are defined as
follows.
M8130 to M8132:
“Disconnect User Communication
Connection”
M8133 to M8137:
“Reserved”
Indirectly M8131
Overflow or Comparison ON
Status
Indirectly M8132 Underflow
Indirectly M8133
High-speed Counter (X3) Comparison ON
Status
Indirectly M8134
High-speed Counter (X4) Comparison ON
Status
Indirectly M8135
High-speed
Counter
(X5-X7)
Preset/Reset Status
Indirectly M8136
Overflow or Comparison ON
Status
Indirectly M8137 Underflow
Indirectly M8140 Interrupt Input X2 Status
Refer to M8070 to M8075 “Interrupt Input
Status” according to the definition for the
FT1A series.
M8140 to M8143 are defined as “Reserved.”
Indirectly M8141 Interrupt Input X3 Status
Indirectly M8142 Interrupt Input X4 Status
Indirectly M8143 Interrupt Input X5 Status
Yes M8144 Timer Interrupt Status
No M8145
User Communication Receive Instruction Cancel
Flag (Port 4)
Not supported by the FT1A series. Port 3
and later are not provided.
M8145 to M8147 are defined as “Reserved.”
No M8146
User Communication Receive Instruction Cancel
Flag (Port 5)
No M8147
User Communication Receive Instruction Cancel
Flag (Port 6)
Yes M8150 Comparison Result Greater Than
Yes M8151 Comparison Result Less Than
Yes M8152 Comparison Result Equal To
- M8153 Reserved
Indirectly M8154 Catch Input X2 ON/OFF Status Refer to M8090 to M8095 “Catch Input
ON/OFF Status” according to the definition
for the FT1A series.
Special internal relays are defined as
follows.
M8154 to M8155
“Data Register ROM Backup”
M8156 to M8157
“Reserved”
Indirectly M8155 Catch Input X3 ON/OFF Status
Indirectly M8156 Catch Input X4 ON/OFF Status
Indirectly M8157 Catch Input X5 ON/OFF Status
Compatibility table (FC4A/5A series -> FT1A series)
59. 59
Special data registers
Replaceability
Special
data
register
FC4A/5A series specifications FT1A series specifications
Yes D8000 CPU Module System (Quantity of Inputs)
Yes D8001
CPU Module System (Quantity of
Outputs)
Yes D8002 CPU Module Type Information
Yes D8003 Memory Cartridge Information
- D8004 Reserved
Yes D8005 General Error Code
Yes D8006 User Program Execution Error Code
No D8007
Communication Mode Switching (Port 1
and 2)
Not supported by the FT1A series. If the
communication setting for the CPU module is
unknown, use a USB port.
Yes D8008 Year (Current Data) Read only
Yes D8009 Month (Current Data) Read only
Yes D8010 Day (Current Data) Read only
Yes D8011 Day of Week (Current Data) Read only
Yes D8012 Hour (Current Data) Read only
Yes D8013 Minute (Current Data) Read only
Yes D8014 Second (Current Data) Read only
Yes D8015 Year (New Data) Write only
Yes D8016 Month (New Data) Write only
Yes D8017 Day (New Data) Write only
Yes D8018 Day of Week (New Data) Write only
Yes D8019 Hour (New Data) Write only
Yes D8020 Minute (New Data) Write only
Yes D8021 Second (New Data) Write only
Yes D8022 Constant Scan Time Preset Value
Yes D8023 Scan Time Current Value (ms)
Yes D8024 Scan Time Maximum Value (ms)
Yes D8025 Scan Time Minimum Value (ms)
Indirectly D8026 Communication Mode Information
Port number allocation is different.
Refer to the port number according to the
definition for the FT1A series.
Indirectly D8027 Port 1 Communication Network Number Port number allocation is different.
Refer to and set the port number according to the
definition for the FT1A series.Indirectly D8028 Port 2 Communication Network Number
Yes D8029 System Program Version
Indirectly D8030 Communication Adapter Information
Port number allocation is different.
Refer to the port number according to the
definition for the FT1A series.
Indirectly D8031 Optional Cartridge Information
Options that can be used in the FT1A series are
different.
Refer to the port number according to the
definition for the FT1A series.
Indirectly D8032
Interrupt Input Jump Destination Label
No. (X2)
The interrupt input port is allocated differently.
Make the setting according to the definition for the
FT1A series.
Indirectly D8033
Interrupt Input Jump Destination Label
No. (X3)
Indirectly D8034
Interrupt Input Jump Destination Label
No. (X4)
Indirectly D8035
Interrupt Input Jump Destination Label
No. (X5)
Compatibility table (FC4A/5A series -> FT1A series)