MAX32626

The Maxim Darwin LoRaWAN^® starter kit brings all the hardware needed to experience and explore the world of the LoRaWAN low-power, wide area network (LPWAN) technology. It includes a highly customizable IoT button as an example for an end device, a development board equipped with a Maxim FMLR module for quick prototyping, and a FMLR-PICOGW LoRaWAN^® gateway for connectivity with a backend and application server.

Furthermore, the IoT button and FMLR-PICOGW are already registered in Miromico’s Loriot backend and can be observed in their IoT dashboard. To use the development board, it needs to be flashed with functional firmware. A simple join example is publicly available and open-sourced at Miromico’s Gitlab. More information can be found in the Quick Start Guides/data sheets.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• MAX32625 Microcontroller
  • ARM Cortex-M4F
  • 512KB Flash, 160KB SRAM
  • FS-USB, UART, SPI, I²C, 1-Wire^®
• nexpaq Compatible
  • nexpaq Module Form Factor
  • nexpaq Interface Connector
• Expansion Connections
  • Power: GND, 3.3V, 5V, Battery
  • Serial I/O: I²C, SPI, UART, 1-Wire
  • Analog Inputs
  • PWM Outputs
  • RGB Indicator LED
  • bed^® HDK DAPLink Connector
  • Drag-and-Drop Programming
  • CMSIS-DAP Debugger
  • Virtual UART Console

The MAX32625NEXPAQ is a rapid development platform designed to accelerate the implementation of nexpaq modules with the MAX32625 ARM^® Cortex^®-M4F microcontroller. It contains all the elements needed to interface to the nexpaq system and provides easy access to the main peripherals inside the microcontroller. This provides an expandable platform for quick proof-of-concepts and early software development to enhance time to market.

The nexpaq platform provides the simplest way to interface hardware to a phone. It utilizes web standards to enable a rich user experience that is fundamentally cross platform.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• Easily Load and Debug Code Using the Supplied Olimex ARM-USB-TINY-H JTAG Debugger Connected Through a Standard 20-Pin ARM JTAG Header
• Selectable Power Sources for PMIC Include USB Power Through the CN1 or CN2 Connector, Optional External Battery Through J2 Connector, or Bench Supply Through Test Points TP8 and TP9
• Selectable Power Source for On-Board Peripherals (Switches, LEDs, OLED Display, SPI Flash, Bluetooth® LE Transceiver)
• Headers for Accessing the IC’s I/O Pins and Analog Front End (AFE) Input Signals
• USB Micro-B Connection to the IC’s USB Device Controller
• USB Micro-B Connection to USB-UART Bridge Selectable Between the IC’s Internal UART 0 and UART 1
• On-Board Bluetooth 4.0 BLE Transceiver with Chip Antenna
• General-Purpose Pushbutton Switches and Indicator LEDs (All Connected to GPIOs) for User I/O
• Prototyping Matrix (0.1in Grid) with Integrated Power Rails for Customer Circuitry

The MAX32625/MAX32626 evaluation kit (EV kit) provides a convenient platform for evaluating the capabilities of the MAX32625/MAX32626 microcontroller. The EV kit also provides a complete, functional system ideal for developing and debugging applications.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• Easily Load and Debug Code Using the Supplied Olimex ARM-USB-TINY-H JTAG Debugger Connected Through a Standard 20-Pin ARM JTAG Header
• Selectable Power Sources for PMIC Include USB Power Through the CN1 or CN2 Connector, Optional External Battery Through J2 Connector, or Bench Supply Through Test Points TP8 and TP9
• Selectable Power Source for On-Board Peripherals (Switches, LEDs, OLED Display, SPI Flash, Bluetooth® LE Transceiver)
• Headers for Accessing the IC’s I/O Pins and Analog Front End (AFE) Input Signals
• USB Micro-B Connection to the IC’s USB Device Controller
• USB Micro-B Connection to USB-UART Bridge Selectable Between the IC’s Internal UART 0 and UART 1
• On-Board Bluetooth 4.0 BLE Transceiver with Chip Antenna
• General-Purpose Pushbutton Switches and Indicator LEDs (All Connected to GPIOs) for User I/O
• Prototyping Matrix (0.1in Grid) with Integrated Power Rails for Customer Circuitry

The MAX32625/MAX32626 evaluation kit (EV kit) provides a convenient platform for evaluating the capabilities of the MAX32625/MAX32626 microcontroller. The EV kit also provides a complete, functional system ideal for developing and debugging applications.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• Arduino-Compatible Headers and mbed Support Enable Rapid Prototyping of Low-Power Embedded Systems
• MAX32625 Microcontroller
  • 96MHz ARM Cortex-M4 Microcontroller with FPU
  • 512KB Flash Memory
  • 160KB SRAM
  • 8KB Instruction Cache
  • Full-Speed USB 2.0
  • Three SPI Masters, One Slave
  • Two I²C Masters, One Slave
  • Three UARTs
  • 1-Wire Master
  • 40 GPIOs
  • Four Input 10-Bit ADC
• Expansion Connections
  • Arduino Form-Factor Headers
  • MicroSD Card Connector
  • Micro-USB Connectors
  • Prototyping Area
• Integrated Peripherals
  • 4x User Indicator LED
  • 2x User Pushbutton
• Integrated DAPLink Programming Adapter
  • Drag-and-Drop Programming
  • CMSIS-DAP SWD Debugger
  • USB Virtual UART

The MAX32625MBED provides a convenient platform for evaluating the capabilities of the MAX32625 microcontroller. The MAX32625MBED also provides a complete, functional system ideal for developing and debugging applications.

The MAX32625MBED includes a MAX32625 ARM^® Cortex^®-M4 microcontroller with FPU, prototyping area with adjacent access to precision analog front end (AFE) connections, I/O access through Arduino^®-compatible connectors, additional I/O access through 100mil x 100mil headers, USB interface, and other general-purpose I/O devices.

Go to https://developer.mbed.org/platforms/MAX32625MBED/ to get started developing with this board.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• Ultra-Compact Development Platform
  • 0.6in x 1.0in, 20-Pin DIP Footprint
  • Cortex Debug Connector (Host)
  • 20 Digital I/O, 4 Analog Inputs
  • 3.3V and 1.8V Supplies
• MAX32625 Microcontroller Features
  • ARM Cortex-M4 Microcontroller with FPU, 96MHz
  • 512KB Flash Memory
  • 160KB SRAM
  • 8KB Instruction Cache
  • Full-Speed USB 2.0
  • Three SPI Masters, One Slave
  • Two I²C Masters, One Slave
  • Three UARTs
  • 1-Wire Master
  • 40 GPIOs
  • Four Input 10-Bit ADC
• MAX14750 PMIC
  • Micro I_Q 3.3V Buck-Boost Regulator
  • Micro I_Q 1.8V Buck Regulators
  • Micro I_Q 1.2V Linear Regulators
  • High-Side Load Switch
• Expansion Connections
  • Breadboard-Compatible Headers
  • SMT-Compatible Footprint
  • 10-Pin Cortex Debug Header
  • Micro USB Connector
• Integrated Peripherals
  • RGB Indicator LED
  • User Pushbutton
• MAXDAP Programming Adapter
  • DAPLink Over Cortex Debug Cable
  • Drag-and-Drop Programming
  • CMSIS-DAP SWD Debugger
  • USB Virtual UART

The MAX32625PICO board is a rapid development platform designed to help engineers quickly implement designs with the MAX32625 ARM^® Cortex^®-M4 microcontroller with FPU. The board also includes the MAX14750 PMIC to provide all the needed voltages. The form factor is a small: 0.6in x 1.0in dual-row header footprint that is compatible with breadboards and can also be soldered down SMT to another board. The board includes a 10-pin ARM Cortex debug connector so that it can be used as a DAPLink adapter. Additionally, on board are an RGB indicator LED and pushbutton. This provides a power-optimized flexible platform for quick proofs-ofconcept and early software development to enhance time to market.

The MAX32625PICO board ships with a DAPLink image loaded that provides the USB Mass Storage Device (MSD) drag-and-drop programming, USB Communications Device Class (CDC) virtual serial port, and Human Interface Device (HID) CMSIS-DAP interface used by the mbed site. This allows the board to be connected to another target platform to enable the full mbed experience. The microcontroller is also programmed with a bootloader allowing the DAPLink image to be updated or replaced with your own application code. Get started developing on this board by going to this link: http://developer.mbed.org/platforms/MAX32625PICO.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches

• USB-Powered Operation
• USB to I²C and SPI Interface
• Pmod Compatible Form Factor
• Flexible Configuration
• MAX32625PICO Rapid Development Platform
• Drag-and-Drop Programming
• Small PCB Area
• Windows^® 8/10-Compatible GUI Software
• Fully Assembled and Tested

The MAXPICO2PMB adapter board is a fully assembled and tested PCB that provides an I²C interface to quickly interact with an evaluation kit (EV kit) or a demo board connected through the Pmod™ connector.

The adapter board features a rapid development platform - the MAX32625PICO microcontroller, jumpers and a Pmod connector. The user can select on-board pullup resistors on the I²C lines by configuring jumpers. It also features an option to select the pullup voltage for the I²C lines through the power rail jumper. The Pmod connector provides one I²C port and two SPI ports for convenient evaluation.

The MAXPICO2PMB Register Map Tool is a Windows application that interfaces with the MAXPICO2PMB adapter board. The user can import *.regmap files that contain the unique I²C register map information and register field descriptions of an integrated circuit. The application sends commands to the MAX32625PICO microcontroller on the MAXPICO2PMB adapter board over a virtual serial port. The MAX32625PICO microcontroller sends I²C commands to communicate with the EV kit or demo board connected through the Pmod connector.

Applications

• Fitness Monitors
• Portable Medical Devices
• Sensor Hubs
• Sports Watches
• Wearable Medical Patches