AD-APARD32690-SL
Overview
The AD-APARD32690-SL is a platform for prototyping intelligent, secure, and connected field devices. It has an Arduino Mega-compatible form factor and two Pmod-compatible connectors. The system includes the MAX32690 ARM Cortex-M4 with FPU-Based Microcontroller and Bluetooth LE 5.2. The MCU is coupled with external RAM (2 x 512 Mb) and Flash (64 Mb) memories to meet the requirements of the most demanding applications. The MAXQ1065 security coprocessor enables state of the art security features such as for root-of-trust, mutual authentication, data confidentiality and integrity, secure boot, and secure communications. A 10 Mbps single-pair Ethernet link using the ADIN1110 10BASE-T1L MAC/PHY, enables remote data acquisition and system configuration. The 10BASE-T1L interface also supports Single-pair Power over Ethernet (SPoE) and be used for powering the system via an Arduino shield implementing the required power circuitry.
The Zephyr port is running on the MAX32690 MCU.
Hardware
MAX32690 MCU:
Ultra-Efficient Microcontroller for Battery-Powered Applications
120MHz Arm Cortex-M4 Processor with FPU
7.3728MHz and 60MHz Low-Power Oscillators
External Crystal Support (32MHz required for BLE)
32.768kHz RTC Clock (Requires External Crystal)
8kHz Always-On Ultra-Low Power Oscillator
3MB Internal Flash, 1MB Internal SRAM (832kB ECC ON)
TBDμW/MHz Executing from Cache at 1.1V
1.8V and 3.3V I/O with No Level Translators
External Flash & SRAM Expansion Interfaces
Bluetooth 5.2 LE Radio
Dedicated, Ultra-Low-Power, 32-Bit RISC-V Coprocessor to Offload Timing-Critical Bluetooth Processing
Fully Open-Source Bluetooth 5.2 Stack Available
Supports AoA, AoD, LE Audio, and Mesh
High-Throughput (2Mbps) Mode
Long-Range (125kbps and 500kbps) Modes
Rx Sensitivity: -97.5dBm; Tx Power: +4.5dBm
Single-Ended Antenna Connection (50Ω)
Multiple Peripherals for System Control
16-Channel DMA
Up To Five Quad SPI Master (60MHz)/Slave (48MHz)
Up To Four 1Mbaud UARTs with Flow Control
Up To Two 1MHz I2C Master/Slave
I2S Master/Slave
Eight External Channel, 12-bit 1MSPS SAR ADC w/ on-die temperature sensor
USB 2.0 Hi-Speed Device
16 Pulse Train Engines
Up To Six 32-Bit Timers with 8mA High Drive
Up To Two CAN 2.0 Controllers
Up To Four Micro-Power Comparators
1-Wire Master
Security and Integrity
ChipDNA Physically Un-clonable Function (PUF)
Modular Arithmetic Accelerator (MAA), True Random Number Generator (TRNG)
Secure Nonvolatile Key Storage, SHA-256, AES-128/192/256
Secure Boot ROM
External devices connected to the APARD32690:
On-Board HyperRAM
On-Board SPI Flash
USB 2.0 Type-C interface to the MAX32690
SPI PMOD connector
I2C PMOD connector
SWD 10-Pin Header
On-Board Bluetooth 5.2 LE Radio antenna
MAXQ1065 Ultralow Power Cryptographic Controller with ChipDNA
ADIN1110 Robust, Industrial, Low Power 10BASE-T1L Ethernet MAC-PHY
U-Blox NINA-W102 802.11b/g/n module with dual-mode Bluetooth v4.2
On-Board 5V, 3.3V, 1.8V, and 1.1V voltage regulators
2-Pin external power supply terminal block (5V - 28V DC)
Board Power Provided by either the USB Port or the 2-Pin connector
Arduino Mega compatible header.
Two general-purpose LEDs and one general purpose push button.
Supported Features
Below interfaces are supported by Zephyr on APARD32690.
Interface |
Controller |
Driver/Component |
---|---|---|
NVIC |
on-chip |
nested vector interrupt controller |
SYSTICK |
on-chip |
systick |
CLOCK |
on-chip |
clock and reset control |
GPIO |
on-chip |
gpio |
UART |
on-chip |
serial |
SPI |
on-chip |
spi |
ADIN1110 |
spi |
ADIN1110 10BASE-T1L mac/phy |
TRNG |
on-chip |
entropy |
Timer |
on-chip |
counter |
W1 |
on-chip |
one wire master |
Connections and IOs
Name |
Name |
Settings |
Description |
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P55 |
SWD TX |
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P50 |
SWD RX |
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P51 |
SWD POW |
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P38 |
UART RX WIFI |
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P58 |
UART TX WIFI |
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S4 |
SW1 |
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S4 |
SW2 |
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S4 |
SW3 |
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Programming and Debugging
Flashing
The MAX32690 MCU can be flashed by connecting an external debug probe to the SWD port. SWD debug can be accessed through the Cortex 10-pin connector, P9. Logic levels are either 1.8V or 3.3V (based on P51 selection).
Once the debug probe is connected to your host computer, then you can simply run the
west flash
command to write a firmware image into flash.
Note
This board uses OpenOCD as the default debug interface. You can also use
a Segger J-Link with Segger’s native tooling by overriding the runner,
appending --runner jlink
to your west
command(s). The J-Link should
be connected to the standard 2*5 pin debug connector (P9) using an
appropriate adapter board and cable.
Debugging
Please refer to the Flashing section and run the west debug
command
instead of west flash
.