Maxim Introduces Ultra-Low-Power BLE 5.2 MCU for IoT Applications

Maxim Introduces Ultra-Low-Power BLE 5.2 MCU for IoT Applications

Designers of wirelessly connected, coin cell-operated internet of things (IoT) products can now reduce bill-of-materials (BOM) costs by one-third while also saving space and battery life with the MAX32666 microcontroller (MCU) from Maxim Integrated Products. This ultra-low-power dual Arm Cortex-M4 MCU with a floating-point unit (FPU) and Bluetooth Low Energy 5.2 (BLE 5.2) extends the device's battery life by combining robust memory, security, communications, power management and processing functions traditionally performed by multiple MCUs into a single device. 

Side Note: Did you know that Analog Devices has acquired Maxim Integrated. Click here to learn more about this.

Key Advantages of the MAXIM Integrated BLE 5.2 MCU

  • Reliability: Adds an extra level of robustness with integrated ECC on Flash, SRAM, and Cache memories, preventing undesirable bit flips.
  • Low Cost: Combines two microcontroller cores, Bluetooth radio with dedicated stack core, power management, security, and significant memory into one IC. Reduces BOM costs by making use of dual 96MHz Cortex-M4 with FPU as well as large on-board memory of 1MB Flash and 560KB SRAM.   
  • Saves Board Space: Integrates multiple functions into a single IC with a small 3.8mm x 4.2mm WLP footprint.
  • Low Power: Preserves battery life of coin-cell battery devices through low active-mode power; Offers dynamic voltage scaling for minimized active core power consumption; Enables 27.3uA/MHz at 3.3V executing from cache memory; Multiple power-down modes support longer battery life, achieving 1.2uA at 3.3V in the lowest power mode.

The MAX32666 MCU is the latest addition to Maxim Integrated's smart, function-rich DARWIN family of high-performance MCUs. In contrast to traditional architectures, this MCU reduces form factor and design footprint, enabling IoT device designers to lower BOM costs by consolidating up to three sockets found in their current designs. 

  • This dual Cortex-M4F MCU provides efficient computation of complex functions, operating at up to 96MHz, which speeds up data processing by 50 percent over the closest competitor. 
  • To replace the need for a separate PMIC, the MAX32666 features an integrated single-inductor, multiple-output (SIMO) regulator, which extends the life for small-sized battery applications. 
  • The MCU offers BLE 5.2, supports up to 2Mbps of data throughput and long-range (125kbps and 500kbps) and offers a transceiver output power of +4.5dBm programmable down to -95dBm. 
  • It also protects applications from cybersecurity threats with the trust protection unit (TPU) and big math acceleration for fast Elliptic Curve Digital Signature Algorithm (ECDSA)
  • The IC's hardware accelerators provide AES-128, -192, and -256 encryption, while TRNG seed generator and SHA-2 accelerator enhance security. 
  • It also protects IP firmware with a secure bootloader. The MAX32666 has an impressive onboard memory capacity with up to 1MB flash memory and 560KB of SRAM with an optional Error Correcting Code (ECC) for the most robust applications, as well as multiple high-speed peripherals. 
  • It can manage more data and accommodate bigger applications without running out of code space through efficient operation – all within a best-in-class power profile.

As IoT applications become more advanced, more MCUs are typically added to the system. Usually, these advanced systems include a dedicated processor to handle the application, another processor acting as a sensor hub, a separate standalone BLE microcontroller to handle the wireless connectivity function, and in many cases, a power management IC (PMIC) to efficiently provide supply voltages to the MCUs. However, this approach is proving to be unsustainable for IoT applications that are growing in complexity while still demanding smaller size and longer battery life.

Click Here to learn more about the MCU.

Publisher: everything RF