Low-power general-purpose 16-bit MCUs

Low-power general-purpose 16-bit MCUs

New Products |
By Jean-Pierre Joosting

Renesas Electronics Corporation is beginning of mass production of its 16-bit general-purpose RL78/G23 microcontroller (MCU), further strengthening its RL78 family of 8-bit and 16-bit MCUs for a broad range of applications. Compatible with its current general-purpose RL78 MCUs, such as the RL78/G13, the RL78/G23 increased the on-chip flash memory capacity to 768 KB and substantially expanded on-chip peripheral functions, which extend functionality while reducing the bill of materials (BOM) cost, while improving power consumption required by battery powered applications. With this feature combination, the new RL78/G23 is well suited for a wide range of applications that require both power and cost efficiency, including IoT endpoint devices such as home electronics, remote controls, and sensors.

“It has been 10 years since we first introduced the RL78 family, and Renesas has continued its technology innovation drive as seen with the new RL78/G23, which delivers lower power consumption with a new process technology,” said Noriaki Nakanishi, Vice President of the MCU Device Solution Business Division at Renesas.

By adopting a new process, the RL78/G23 realizes 44 µA/MHz at CPU operation and 210 nA during STOP (with 4KB of SRAM retention), an even lower power consumption compared to current RL78 MCUs. In addition, the newly implemented SNOOZE mode sequencer (SMS) makes it unnecessary to activate the CPU while any peripheral operations are operating in snooze mode, dramatically reducing power consumption for applications that utilize intermittent operation. Furthermore, the logic and event link controller (ELCL) adds logic functionality to the capabilities of a conventional event link controller (ELC). This makes it possible to create conditional links to multiple events while continuing to benefit from the reduced power consumption realized by the ELC.

The RL78/G23 features a Renesas-exclusive capacitive touch sensor unit that combines superior high-sensitivity and low-noise characteristics and can be used to implement a contactless gesture-based user interface (UI). The MCUs also incorporate enhanced security functions that make it possible to develop truly secure systems. These include a true random number generator (TRNG) essential for certificate encryption as well as a device-specific unique ID and a customer ID that can be specified by the user. Renesas also provides the RL78/G14 evaluation board, which is already qualified to work with FreeRTOS on Amazon Web Services (AWS) and is listed in the AWS Partner Device Catalog. The RL78/G23 evaluation board is also scheduled to receive FreeRTOS qualification.

Key features include:

  • RL78 CPU core running at 32 MHz;
  • Support for operating voltages ranging from 1.6 V to 5.5 V;
  • Maximum 768 KB of code flash memory, 8 KB of data flash memory, maximum 48 KB of SRAM,  to support software updates, etc;
  • On-chip capacitive touch sensor unit that can be used to implement a high-sensitivity contactless UI;
  • High-precision (±1.0%), high-speed on-chip oscillator;
  • Analog functions such as 12-bit A/D converter, 8-bit D/A converter, and temperature sensor, etc;
  • Remote control signal reception function, enabling one-chip implementation of a remote control receiver;
  • Output current control (15 mA) port for LED drive and 40 mA output port;
  • Package lineup with pin counts from 30 to 128 pins.

An evaluation board (the Fast Prototyping Board) is now available for the RL78/G23 that features all-pin access as well as Arduino UNO and Grove interfaces. Simply connect a USB cable to enable program writing and debugging, enabling developers to start evaluation of the RL78/G23 without the need for additional tools. In addition, there is a rich development environment available for the RL78/G23 that includes, in addition to previously available development tools for the RL78 family, Smart Configurator, which simplifies SMS and ELCL design and supports peripheral function driver code generation via a GUI, a QE tool for touch panel tuning, and the Arduino development environment (IDE).

If you enjoyed this article, you will like the following ones: don't miss them by subscribing to :    eeNews on Google News


Linked Articles