系统板 6782

Go-IO工业IoT参考设计



Go-IO为工业物联网(IIoT)参考设计,旨在快速开发可配置工业控制系统以及搭建原型。典型最终应用包括工业4.0驱动的过程自动化,广泛应用于智能建筑、智能传感器、可配置工业控制系统以及机器人。所有这些工业应用都要求高性能、可靠的可配置方案,Go-IO利用模块化方法满足了此类要求。这些系统依赖于Maxim Integrated提供的高度集成IC,在实现新性能水平的同时提供更低功耗、微小外形尺寸。

Go-IO具有四种不同的电路板。不同的配置可实现各种I/O通道和通信接口类型的混合搭配,满足不同的最终应用。

设计资源标签页可下载设计文件、固件及软件。提供电路板供用户购买。

特性

  • 8通道隔离数字输入
  • 4通道隔离1.2A数字输出,带安全/快速消磁
  • 4端口®主机版本1.1,兼容TMG IO-Link主机堆栈
  • 1个隔离电源和RS-485 COM端口,全双工25Mbps数据率

应用

  • 工业IOT
  • 工业4.0和机器人
  • 工厂和过程自动化
  • IO-Link传感器和执行器
  • 楼宇自动化
Go-IO System Board 放大+

Go-IO is the brand name for a modular Industrial IoT reference design (see Figure 1) based on a carrier card (or backplane) (MAXREFDES215#), an application processor card (MAXREFDES211#), and an I/O card which can vary depending upon the target application (MAXREFDES200#, MAXREFDES201#). The MAXREFES200# targets factory automation and features a mix of I/O types including analog inputs, analog output, digital input, digital output, IO-Link and a RS-485 COM port. The MAXREFES201# targets motion control and features a mix of I/O types including digital inputs, DC motor drivers, encoders, and a RS-485 COM port.

All field connectors are on the MAXREFDES215# carrier card for easy connectivity to sensors, actuators, and communication ports. All cards are powered from a single 24V wall adapter, which connects to the carrier card. Circuitry on the carrier card generates various power rails including an isolated supply for the application processor card (MAXREFDES211#). Additional local on-card DC-DC converters and LDO regulators are used to create lower voltage rails specific to each card.

Order the MAXREFDES212# to receive a kit that contains the MAXREFDES215#, MAXREFDES211#, MAXREFDES200#, and a 24V wall adapter. The kit allows the Go-IO system to be used out-of-the-box.

Go-IO System Board 放大+

 

Diagram 放大+

System Diagram

When plugged together, the Go-IO boards form a configurable development reference design for industrial IOT applications. The system provides a robust, flexible architecture which leverages leading edge industrial technologies for Universal I/O, isolation, power management, and Arm®-based microcontrollers. Featuring highly integrated solutions, these boards support over 20 I/Os in a tiny footprint of less than three square inches. The compact footprint and high reliability are achieved by using highly efficient power management and low power dissipation devices, which are available in tiny packages.

Go-IO modular block diagram
Figure 1. Go-IO modular block diagram.

Detailed Description of the MAXREFDES215# Carrier Card

Introduction
Figure 2 shows the system block diagram for the MAXREFDES215#.


Figure 2. MAXREFDES215# block diagram.

Figure 3 shows the top view of the MAXREFDES215#.


Figure 3. MAXREFDES215# top view.

Connections
Two connectors are used for board-to-board interfaces: J1 and J2. J1 is an 80-way female connector that mates with a male connector on an I/O card, which can be either the MAXREFDES200# or the MAXREFDES201# depending upon the end application. J2 is a 30-way male connector that mates with a female connector on the MAXREFDES211# application processor card. Both connectors are keyed to prevent incorrect insertion of the respective cards.

Four M12 type female connectors are used to connect to industry-standard IO-Link sensors and actuators that use equivalent M12 male connectors and cables. Multiple screw terminal blocks are used for easy connection to the analog I/O, digital I/O and RS-485 ports.

Galvanic Isolation
The Go-IO uses two different domains, which are separated using the Maxim digital isolator products. The field domain uses the 24V input supply and 24V GND for reference. The logic domain uses APP_PWR and APP_GND for reference and is found on the application processor card, MAXREFDES211#.

Power Supplies
Power is supplied to the MAXREFDES215# using a standard 24V, 1A wall adapter that connects to the on-board barrel connector. Alternatively, a higher current power supply of up to 5A can be connected using screw terminals on block J9.

The 24V input rail is protected from overcurrent with a 1A fuse. If the MAXREFDES200# is used and if a higher current operation is required (i.e., digital output loads greater than 1A), an external 24V supply can be connected to the input terminal on connector J9. If the MAXREFDES201# is used with the DC motor drivers, the VMTR supply must be connected to the input terminal J3. The power supply must match the DC motor selected for voltage and current specifications.

With the 24V input, different DC-DC converters are used to generate different voltage rails. The MAX17681 is a high-efficiency iso-buck DC-DC converter used to provide isolated power up to 5W. In the MAXREFDES215#, the input is 24V and the MAX17681 uses primary-side feedback to regulate the output voltage while reducing the external components and saving total cost, no optocoupler required. After the transformer output and rectification, the MAX17608 current limiter provides the isolated power rails APP_PWR and APP_GND. The MAX17608 is the industry's smallest and most robust integrated system protection solution, providing 1A current limiting along with OV, UV, and reverse protection.

On the field domain, two regulators generate the higher positive and negative voltage rails, HVDD and HVSS, to be used by the analog IO products. The MAX17608 provides a protected 24V rail, V24_PROT, which in turn becomes the HVDD rail. The MAX15062 high-efficiency step-down DC-DC converter converts the +24V input to a negative voltage rail for use as the HVSS supply to be used by the analog IO products.

Detailed Description of the MAXREFDES211# Application Processor

Introduction
Figure 4 shows the system block diagram for the MAXREFDES211#.


Figure 4. MAXREFDES211# block diagram.

Figure 5 shows a picture of the top view of the MAXREFDES211#.


Figure 5. MAXREFDES211# top view.

Connections
The MAXREFDES211# connects to the underside of the MAXREFDES215# through a 30-way female connector that mates with a male connector on the MAXREFDES215# carrier card. Both connectors are keyed to prevent incorrect insertion of the respective cards. Three USB connectors are included for interfacing to the MAX32630 microcontroller.

Galvanic Isolation
The Go-IO uses two different domains, which are separated using the Maxim digital isolator products. The field domain uses the 24V input supply and 24V GND for reference. The logic domain uses APP_PWR and APP_GND for reference and is found on the application processor card, MAXREFDES211#. The digital isolators on the I/O control card, either MAXREFDES200# or MAXREFDES201#, perform the galvanic isolation function.

Power Supplies
Power is supplied to the MAXREFDES211# from the MAXREFDES215# (APP_PWR (24V) and APP_GND). On board regulators do a multi-level step down to provide the different voltage rails required by the microcontroller.

The MAX17502 DC-DC converter steps the 24V input down to 3.3V to use as the input to the two MAX1806 linear regulators. The MAX17502 high-efficiency, high-voltage, synchronous step-down DC-DC converter with integrated MOSFETs operates over a 4.5V to 60V input voltage range. This device is offered in a fixed 3.3V output voltage while delivering up to 1A of current. The output voltage is accurate to within ±1.7% over -40°C to +125°C.

The MAX1806 low-dropout linear regulator operates from a +2.25V to +5.5V supply and delivers a guaranteed 500mA load current with low 175mV dropout. The high-accuracy (±1%) output voltage has different preset values, and for the MAXREFDES211#, two MAX1806 linear regulators generate the 1.8V and 1.2V rails required by the MAX32630 microcontroller.

Microcontroller
The MAX32630 features an Arm Cortex®-M4 with FPU CPU that delivers ultra-low power, high-efficiency signal processing functionality with significantly reduced power consumption and ease of use. Multiple SPI, UART, I2C, 1-Wire® master, and USB interfaces are provided. The USB interfaces are made using industry standard FTDI USB chips.

The MAXREFDES211# uses four SPI buses to interface to the different peripherals:

  • MCU_SPI: Use the 2:1 jumper to select the target SPI bus, either a secondary FTDI-USB interface or the more commonly used APP_SPI1 bus. The APP_SPI1 bus connects to the 80-way connector to plug-in modules such as the MAXREFDES200# or MAXREFDES201#. This SPI bus is galvanically isolated on those cards and used to control I/O peripherals such as the MAX14819 IO-Link master IC.
  • APP_SPI2: The APP_SPI2 bus connects to the 80-way connector to plug-in modules such as the MAXREFDES200# or MAXREFDES201#. On the MAXREFDES200# or MAXREFDES201#, this SPI bus connects to the MAX22192, which is a galvanically isolated digital input device. The integrated isolation within the MAX22192 shares the isolated SPI bus with other field domain devices on the modules, saving the need for more external isolators.
  • WIFI_SPI: The WIFI_SPI bus connects to the Wi-Fi chipset and is unused in the initial product release.
  • SD_SPI: The SD_SPI bus connects to the SD card controller and is unused in initial product release.

Detailed Description of the MAXREFDES200# Factory Automation Module

Introduction
Figure 6 shows the system block diagram for the MAXREFDES200#.



Figure 6. MAXREFDES200# block diagram.

Figure 7 shows the top view of the MAXREFDES200#.


Figure 7. MAXREFDES200# top view.

Connections
The MAXREFDES200# connects to the top side of the MAXREFDES215# through an 80-way male connector that mates with a female connector on the MAXREFDES215# carrier card. Both connectors are keyed to prevent incorrect insertion of the respective cards.

Galvanic Isolation
The Go-IO uses two different domains, which are separated using the Maxim digital isolator products. The field domain uses the 24V input supply and 24V GND for reference. The logic domain uses APP_PWR and APP_GND for reference and is found on the application processor card, MAXREFDES211#. Three Maxim digital isolators perform the galvanic isolation function on the MAXREFDES200# I/O control card. The MAX14483 and two MAX14130 isolate the SPI buses and control signals (i.e., chip selects, R/W lines).

The MAX14483 is a 6-channel, 3.75kVRMS digital galvanic isolator using Maxim's proprietary process technology. The six signal channels are individually optimized for SPI applications and include very low propagation delay on the SDI, SDO, and SCLK channels. For the MAXREFDES200#, the MAX14483 isolates the APP_SPI1 bus to form the FLD_SPI1 bus that interfaces to the local MCU used for IO-Link master functionality.

The MAX14130 is a 4-channel, 1kVRMS digital isolator utilizing Maxim's proprietary process technology in smaller footprint QSOP packages. This product has four unidirectional channels making it ideal for isolating control signals.

The MAX14130 and MAX14483 transfer digital signals between circuits with different power domains at ambient temperatures up to +125°C. Independent 1.71V to 5.5V supplies on each side of the isolator also make the device suitable for use as a level translator, although this functionality is not used on the MAXREFDES200#. VDD_IO provides logic domain power for the isolators, which is generated by using the integrated LDO within the MAX22192. 3V3_MCU provides the field domain power for the isolators, which is generated on the MAXREFDES200#.

The MAX22192 provides additional isolation as an industrial, octal, digital input device with integrated isolation.

Power Supplies
Power is supplied to the MAXREFDES200# from the MAXREFDES215# (24V) and on-board regulators that step down to provide the different voltage rails required by the I/O devices and digital isolators.

The MAXM15462 is a high-efficiency, synchronous step-down DC-DC module with integrated controller, MOSFETs, compensation components, and inductor that operates over a wide input-voltage range. The module operates from 4.5V to 42V input and delivers up to 300mA output current over a programmable output voltage from 0.9V to 5V. The module significantly reduces design complexity, manufacturing risks, and offers a true plug and play power/supply solution, reducing time-to-market.

Two modules generate 3.3V outputs, 3V3_DIO for powering the I/O interfaces, and 3V3_MCU for powering the local MCU, the IO-Link masters, and the field supply for the digital isolators.

The MAX22191 has an integrated LDO which generates a 3.3V output from the 24V supply, to provide the rail VDD_IO.

IO Interfaces
The MAXREFDES200# has a range of digital I/O (DIO) and analog I/O as well as communication interfaces to represent the functionality commonly found within an industrial system, such as a Programmable Logic Controller (PLC) and its associated I/O modules.

Digital Inputs (DI)
The MAX22192 is an IEC 61131-2 compliant industrial digital input device with integrated isolation. The MAX22192 translates eight 24V current-sinking, industrial inputs to an isolated serialized SPI-compatible output that interfaces with 1.71V to 5.5V logic voltage. A current setting resistor allows the MAX22192 to be configured for Type 1, Type 2, or Type 3 inputs. In the MAXREFDES200#, the inputs are configured at Type 1 or Type 3. For proximity switches, the field wiring is verified using the wire break feature.

The MAX22192 has an isolated 4-pin SPI interface and the field-side accepts a single 7V to 65V supply to the VDD24F pin. When powered by the 24V field supply, the MAX22192 generates a 3.3V output on the VDD3F pin from an integrated LDO regulator, which can provide up to 25mA of current for external loads in addition to powering the MAX22192. In MAXREFDES200#, this output is the VDD_IO rail and is used to power the field domain of the standalone digital isolators, MAX14430 and MAX14483.

The MAX22192 isolates the SPI bus and provides field domain signals that allow other field domain SPI devices to be shared with the MAX22192 and to share its isolation channels. In the MAXREFDES200#, the daisy chained SPI bus is called FLD_SPI2 and connects to the digital output, analog I/O, and UART devices.

Digital Outputs (DO)
The MAX14912 is a digital-output, octal, high-speed, high-side switch/push-pull 24V driver capable of 200kHz switching rate. The MAX14912 has eight 640mA smart high-side switches that can also be configured as push-pull drivers for high-speed switching. The device is configured and controlled through the SPI interface. Care needs to be taken when selecting the output loads to ensure they do not exceed the 1A capability of the power adapter supplied. For higher currents, a different external 24V supply is required.

In the MAXREFDES200#, the MAX14912 is configured to operate in high-side mode and the outputs are connected in pairs (1-2, 3-4, 5-6, 7-8), giving four outputs providing higher current capabilities. This configuration still supports internal safe demagnetization when switching inductive loads and does not require external diodes to dissipate the stored energy.

Communication Ports
The MAXM22511 isolated RS-485/422 module with transceiver and power features a full-duplex isolated RS-485 interface. This full-duplex isolated RS-485/422 transceiver provides 2500VRMS of galvanic isolation between the cable-side (RS-485 driver/receiver side) and the UART side of the device. An integrated DC-DC powers the cable side of the module that requires no external components and removes the need for a separate field domain supply.

The MAXM22511 operates from a single 3.3V supply (3V3_DIO) and the integrated DC-DC converter generates the 3.3V operating voltage for the cable side of the module. The MAXM22511 connects to a MAX3108 UART and has a high ±15kV ESD performance and up to 25Mbps data rate.

UART
The MAXM22511 RS-485 transceiver TX and RX pins connect to a MAX3108 advanced universal asynchronous receiver-transmitter (UART), which has 128 words of receive and transmit first-in/first-out (FIFO) and connects using a high-speed SPI interface to the isolated field SPI bus and, thereafter, the application processor MCU.

IO Link Master
The MAXREFDES200# uses two MAX14819 dual-channel IO-Link master transceivers with a STM32F412 MCU that supports TMG's stack for implementing a 4-channel IO-Link master.

The MAX14819 low-power, dual-channel, IO-Link master transceiver with sensor/actuator power-supply controllers is fully compliant with the latest IO-Link and binary input standards and test specifications, IEC 61131-2, IEC 61131-9 SDCI, and IO-Link 1.1.2. This master transceiver also includes two auxiliary digital input (DI_) channels. The MAX14819 also features autonomous cycle timers, reducing the need for accurate controller timing. Integrated establish-communication sequencers also simplify wake-up management. The MAX14819 integrates two low-power sensor supply controllers with advanced current limiting, reverse current blocking, and reverse polarity protection capability to enable low-power robust solutions.

The 4-port IO-Link master uses TMG's IO-Link master stack, with the software running on a STM32F412 Arm Cortex-M4 microcontroller. Each of the two MAX14819 transceivers connect to a UART in the STM32F412 as well as through a local SPI bus for configuration. The MAXREFDES200# ships with the master stack preprogrammed inside with an indefinite time license.

For further information about TMG and their software, contact Technologie Management Gruppe, Technologie und Engineering GmbH:

Technologie Management Gruppe
Technologie und Engineering GmbH
Zur Gießerei 10
76227 Karlsruhe
Germany
Phone: +49721828060
Email: willems@tmgte.de
Web: www.tmgte.com

Detailed Description of the MAXREFDES201# Motion Control Module

Figure 8 shows the system block diagram for the MAXREFDES201#.


Figure 8. MAXREFDES201# block diagram.

Figure 9 shows the top view of the MAXREFDES201#.


Figure 9. MAXREFDES201# top view.

Connections
The MAXREFDES201# connects to the top side of the MAXREFDES215# through an 80-way male connector that mates with a female connector on the MAXREFDES215# carrier card. Both connectors are keyed to prevent incorrect insertion of the respective cards.

Galvanic Isolation
The Go-IO uses two different domains, which are separated using the Maxim digital isolator products. The field domain uses the 24V input supply and 24V GND for reference. The logic domain uses APP_PWR and APP_GND for reference and is found on the application processor card, MAXREFDES211#. Four Maxim digital isolators perform the galvanic isolation function on the MAXREFDES201# I/O control card. The MAX14130 (3 off) and MAX14483 isolate the SPI bus chip selects and other control signals (i.e., PWM, encoder lines). VDD_IO provides the logic domain power for the isolators and is generated using the integrated LDO within the MAX22192. 3V3_DIO provides field domain power for the isolators and is generated on the MAXREFDES201# card. The MAX22192 provides additional isolation and is an industrial octal digital input device with integrated isolation.

Power Supplies
Power is supplied to the MAXREFDES201# from the MAXREFDES215# (24V), and on-board regulators step down to provide the different voltage rails required by the I/O devices and digital isolators.

The MAXM15462 is a high-efficiency, synchronous step-down DC-DC module with integrated controller, MOSFETs, compensation components, and inductor that operates over a wide input-voltage range. The module operates from 4.5V to 42V input and delivers up to 300mA output current over a programmable output voltage from 0.9V to 5V. The module significantly reduces design complexity, manufacturing risks, and offers a true plug and play power/supply solution, reducing time-to-market.

One module generates a 3.3V output (3V3_DIO) used for powering the I/O interfaces and the field supply for the digital isolators. A second module generates a 5.0V output (5v0_DIO) used as one of the supplies for the MAX14890 encoders.

The MAX22192 has an integrated LDO which generates a 3.3V output from the 24V supply to provide the rail VDD_IO.

IO Interfaces
The MAXREFDES201# has a range of digital input and motor control interfaces as well as communication interfaces.

Digital Inputs
The MAX22192 is an IEC 61131-2 compliant industrial digital input device with integrated isolation. In the MAXREFDES211# three of the eight inputs are used to provide Type 1 or Type 3 interfaces. The MAX22192 has an isolated 4-pin SPI interface.

The MAX22192 isolates the APP_SPI2 bus and provides field domain signals to allow other field-side SPI devices to be shared with the MAX22192 and to share its isolation channels. In the MAXREFDES201#, the shared SPI bus is called FLD_SPI2 and connects to the encoder and UART devices. The MAX22192 is powered by a 24V field supply and generates a 3.3V output on the VDD3F pin from an integrated LDO regulator, which is used to power the MAX22192 and the field domain (VDD_IO) of the standalone digital isolators, MAX14430, and MAX14483.

DC Motor Drivers
The MAX14870 motor drivers provide a small, low-power and simple solution for driving and controlling the brushed DC motors and relays with voltages between 9V and 35V. Very low driver on-resistance reduces power dissipation. Input power for theses circuits is supplied by the green connector. In the MAXREFDES201#, four motor drivers are included, each supporting peak loads up to 2A. All motor driver control signals (i.e., EN, DIR, PWM) are connected to the application processor, MAXREFDES211#, through the digital isolators.

Encoders
The MAX14890E incremental encoder receiver contains four differential receivers and two single-ended receivers. The differential receivers can be operated in RS-422 or differential high-threshold logic (HTL) modes and are optionally configurable for single-ended TTL/HTL operation. The MAXREFDES201# uses three encoders. Each encoder has A, B, and Z differential inputs and an SPI interface that provides diagnostics and individual configurations for each receiver. The three MAX14890E encoders are daisy chained and connected to the isolated field domain SPI bus, FLD_SPI2.

Communication Ports
The MAXM22511 isolated RS-485/422 module with transceiver and power features a full-duplex isolated RS-485 interface. This full-duplex isolated RS-485/422 transceiver provides 2500VRMS of galvanic isolation between the cable-side (RS-485 driver/receiver side) and the UART side of the device. An integrated DC-DC powers the cable side of the module that requires no external components and removes the need for a separate field domain supply.

The MAXM22511 operates from a single 3.3V supply (3V3_DIO) and the integrated DC-DC converter generates the 3.3V operating voltage for the cable side of the module. The MAXM22511 connects to a MAX3108 UART and has a high ±15kV ESD performance and up to 25Mbps data rate.

UART
The MAXM22511 RS-485 transceiver TX and RX pins connect to a MAX3108 advanced universal asynchronous receiver-transmitter (UART), which has 128 words of receive and transmit first-in/first-out (FIFO) and connects using a high-speed SPI interface to the isolated field SPI bus and, thereafter, the application processor MCU.

Quick Start Guide

The Go-IO industrial IoT reference design can be used to control IO-Link, digital input (DI), digital output (DO), and RS-485 devices. This quick start guide shows how to get the system up and running to exercise these IO peripherals.

Required Equipment:
Maxim Supplied:

  • MAXREFDES200# Go-IO Factory Automation Board
  • MAXREFDES211# Application Processor Board
  • MAXREFDES215# Carrier Board
  • 24V 1A DC Wall Adapter

User supplied:

  • Windows® 7, Windows 8, Windows 10 PC with USB port
  • Micro USB 2.0 cable
  • Devices (IO-Link device, RS-485 device, DI device, DO device)
  • Cables to connect devices (M12 or wires)
  • Terminal program such as PuTTY
  • FTDI COM port drivers

Initial Setup Procedure

  1. Connect the MAXREFDES200# to the carrier board MAXREFDES215#.

    insert board connect 1

  2. Connect the MAXREFDES211# to the carrier board MAXREFDES215#.

    insert board connect 2

  3. Connect any other I/O devices to the respective I/O connectors.
  4. Power boards by connecting the 24V DC power adapter into an outlet and into the barrel connector on the MAXREFDES215# carrier board.
  5. Download and install the FTDI drivers for COM port functionality. Go to https://www.ftdichip.com/Drivers/CDM/CDM21228_Setup.zip.
    • Unzip the folder and double click the executable file to install the drivers.

      insert FTDI Install

  6. If not already installed, download a terminal program such as PuTTY.
  7. Connect the micro USB cable to the PC and to CN1 on the MAXREFDES211#.

    insert board usb

  8. When the device is powered and connected, open PuTTY and select "Session" in the left panel.
    • Select the connection type to "Serial."
    • In the "Speed" field, enter 115200.
    • In the "Serial line" field, enter the COM port "COMxxx," where xxx is replaced with the port number. To check the port number, open the Device Manager and unplug and re-plug to see which USB Serial Port disappears and reappears.

      insert PuTTY Session 1

  9. Select "Terminal" in the left panel.
    • Mark the check box for "Implicit CR in every LF."
    • For local echo, select the radio button "Force on."
    • For local line editing, select the radio button "Force on."

      insert PuTTY Terminal 1

  10. It is recommended to go back to "Session" in the left panel and save the session so that the settings can be easily reopened.
  11. Once saved, click "Open."
  12. If there is an empty terminal window, press "a" and "Enter" to display the main menu.

    insert GUI MainMenu

  13. Follow the terminal prompts to exercise the desired I/O.

Self-test Procedure
The self-test can help ensure that the Go-IO is operating as expected.

  1. Complete the Initial Setup Procedure.
  2. Remove power from the MAXREFDES215# before making new connections.
  3. To run the full self-test, connect the following on the MAXREFDES215#:
    • DO1 → DI1 (IO_09+ → IO_01+)
    • DO2 → DI3 (IO_10+ → IO_03+)
    • DO3 → DI5 (IO_11+ → IO_05+)
    • DO4 → DI3 (IO_12+ → IO_07+)
    • Connect each of the four IO-Link ports to a MAXREFDES27# (not supplied) or four other user-supplied IO-Link sensors
  4. Reconnect power to the MAXREFDES215#.
  5. Connect the USB cable to the PC and CN1 of the MAXREFDES211#.

    insert board usb

  6. Open the PuTTY program and load the previously saved settings to connect.
  7. Press "a" and then press "Enter" to show the main menu.
  8. Press "1" and "Enter" to run the self-test.

    insert GUI_SelfTest

  9. The self-test program runs three tests for each IO-Link port.
    • Initial test establishes a connection.
      • If all connections are made, you should see 0 failure totals, and a final PASS result.
      • If all connections are not made, a connection error has occurred, and the module is unusable.
    • Vendor ID and device ID tests. The test program assumes the IO-Link sensor on each IO-Link port is the MAXREFDES27# and looks for the vendor ID and device ID. If an alternative sensor is used and a non-zero value is returned for each ID, the test does not provide a FAIL result.
  10. The user must manually check that the reported values for the vendor ID and device ID (reported in the GUI) are correct and match the values for the IO-Link sensor IODD file.

1-Wire is a registered trademark of Maxim Integrated Products, Inc.
Arm is a registered trademark and registered service mark of Arm Limited.
Cortex is a registered trademark of Arm Limited.
IO-Link is a registered trademark of Profibus User Organization (PNO).
Maxim is a registered trademark of Maxim Integrated Products, Inc.
Maxim Integrated is a trademark of Maxim Integrated Products, Inc.
Wi-Fi is a registered certification mark of Wi-Fi Alliance Corporation.
Windows is a registered trademark and registered service mark of Microsoft Corporation.

Quick Start Guide

The Go-IO industrial IoT reference design can be used to control IO-Link, digital input (DI), digital output (DO), and RS-485 devices. This quick start guide shows how to get the system up and running to exercise these IO peripherals.

Required Equipment:
Maxim Supplied:

  • MAXREFDES200# Go-IO Factory Automation Board
  • MAXREFDES211# Application Processor Board
  • MAXREFDES215# Carrier Board
  • 24V 1A DC Wall Adapter

User supplied:

  • Windows® 7, Windows 8, Windows 10 PC with USB port
  • Micro USB 2.0 cable
  • Devices (IO-Link device, RS-485 device, DI device, DO device)
  • Cables to connect devices (M12 or wires)
  • Terminal program such as PuTTY
  • FTDI COM port drivers
Initial Setup Procedure
 
Status:
Package:
Temperature:

MAXREFDES200#不作为单独参考设计进行销售,只随购买MAXREFDES212#时附带提供。

MAX22192
八通道工业数字输入方案,带诊断功能和数字隔离

  • 高集成度减少BOM数量和电路板空间
  • 低功耗、低发热
  • 内部诊断提高容错能力

MAXM22511
2.5kVRMS、完全隔离型RS-485/RS-422模块收发器 + 电源

  • 节省空间的方案
  • 高性能收发器支持灵活的设计
  • 集成保护,支持可靠的通信

MAX14430
四通道、快速、低功耗、3.75kVRMS数字隔离器

  • 为高速数字信号提供可靠的电气隔离
  • 低功耗
  • 多种选项,支持多种应用

MAX14483
6通道、低功耗、3.75kVRMS、SPI数字隔离器

  • 节省空间、减少外部元件
  • 为SCLK、SDI和SDO信号提供超低传输延迟
  • 可靠的数字信号电隔离

MAX17608
4.5V至60V、1A、OV/UV/反向电压保护器,带正向/反向限流

  • 可靠保护减降低系统停工风险
  • 灵活设计提供设计重复使用率,较少重复验证
  • 节省电路板面积,减少外部BOM

MAXM15462
4.5V至42V、300mA、喜马拉雅uSLIC降压型电源模块

  • 容易使用
  • 高效
  • 灵活的设计

MAX14819
双通道IO-Link主机收发器,集成成帧器和L+电源控制器

  • 低功耗结构
  • 集成IO-Link成帧器无需外部UART
  • 高度可配置、高度集成减少SKU
  • 集成保护,支持可靠的系统
    • 所有接口引脚上提供极性反接保护
    • C/Q和DI完全符合IEC 61131-2标准
    • C/Q兼容IO-Link 1.1.2

  • MAX14912
    八通道、高速、高边开关/推挽式驱动器

    • 低功耗和散热
    • 快速开关,理想用于高速控制系统
    • 工作可靠

    MAX32630
    超低功耗Arm Cortex-M4,带有基于FPU的微控制器(MCU),带有2MB闪存和512KB SRAM

    • 用于可穿戴设备的高效微控制器
    • 电源管理最大程度延长电池应用的工作时间
    • 最优外设组合,提高平台扩展性

    MAX14890E
    增量式编码器接口,适用于RS-422、HTL和TTL,带数字输入

    • 高灵活性,支持所有编码器类型
    • 集成的故障检测功能减少停工时间
    • 集成保护,支持可靠的通信

    MAX14130
    四通道、 1kVRMS、2.75kVRMS及3.75kVRMS数字隔离器

    • 可靠的数字信号电隔离
    • 直接连接绝大多数微控制器和FPGA
    • 多种选项支持宽范围应用

    MAX14870
    紧凑的4.5V至36V全桥式直流电机驱动器

    • 小型封装处理高功率并减小外形尺寸
    • 低功耗,工作温度较低、时间较长
    • 简化设计,缩短上市时间

    MAX17681
    4.5V至42V输入、高效、Iso-Buck DC-DC转换器

    • 减少外部元件,降低总体成本
    • 缩减DC-DC稳压器库存清单
    • 降低功耗

    MAX15062
    60V、300mA、超小尺寸、高效、同步降压型DC-DC转换器

    • 无需外部元件,降低总体成本
    • 缩减DC-DC稳压器库存清单
    • 降低功耗

    MAX17502
    60V、1A、超小尺寸、高效率、同步降压DC-DC转换器

    • 无需外部元件,降低总体成本
    • 减少DC-DC稳压器库存清单
    • 降低功耗

    MAX3108
    SPI/I²C UART,具有128字FIFO,WLP封装

    • 24Mbps (最大)波特率
    • 集成PLL和分频器
    • 1.71V至3.6V电源范围

    MAX1806
    500mA、低电压、线性稳压器,µMAX封装

    • Guaranteed 500mA Output Current
    • Output Down to 0.8V
    • Low 175mV Dropout at 500mA


    The Evolution of PLC: electronica 2018
    0:42 min
    October 2018



    How to Quickly Start Up the Go-IO PLC Reference Design
    4:00 min
    November 2018



    Introducing the Go-IO PLC Reference Design
    2:00 min
    November 2018



    Programming the Go-IO PLC Reference Design with Eclipse
    6:00 min
    November 2018