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Full-Featured Bluetooth 5 Reference Design Powered by Energy Harvesting

November 13, 2018 by Paul Shepard

ON Semiconductor is defining new levels of ultra-low power operation in the IoT with the introduction of its Bluetooth Low Energy Switch reference design that operates entirely from harvested energy. The platform demonstrates how the RSL10 System-in-Package (SIP) can enable Bluetooth 5 devices that are battery-less and entirely self-powered, requiring no additional energy source. Application examples include wall and lighting control, building automation, and asset tracking.

The Energy Harvesting Bluetooth Low Energy Switch brings together the highly integrated and exceedingly low-power RSL10 SIP with the innovative energy-harvesting technology developed by ZF Friedrichshafen AG, to provide a platform for a range of IoT applications. Featuring a fully-integrated antenna, RSL10 radio, and all passive components; the RSL10 SIP simplifies system design and minimizes the Bill of Materials.

The Switch reference design is provided with complete BoM, schematics, PCB layout and Gerber files, as well as free use of the switch-side firmware. The source code included provides a platform from which to develop application code, and the documentation includes detailed explanations of how to customize the firmware and connect the reference design to a Bluetooth Low Energy scanner application running on a smart phone or tablet.

Exclusive new features of the switch include the absence of a buck/boost converter for simplified design-in and improved performance, as well as a smart dimming function.

The technology developed by ZF captures the energy transferred when a user presses a button. The switch converts energy from kinetic to electromagnetic, and stores it for use by the RSL10 SIP. Each time the button is pressed the fully integrated energy harvesting solution generates 300 μJ. This is enough to meet the extremely low power requirements of the RSL10 SIP, which is just 62.5nW in deep sleep and only 10mW when transceiving.

Wiren Perera, who heads IoT at ON Semiconductor said: "Energy harvesting is becoming increasingly important for IoT deployments since it eliminates the need for power delivery, battery costs and replacement costs coupled with its inherent eco-friendliness. Based on the industry's lowest power Bluetooth radio, the Energy Harvesting Bluetooth Low Energy Switch is the perfect starting point for self-powered Bluetooth IoT applications. Along with the reference hardware design, ON Semiconductor provides a firmware suite, which can be customized using the RSL10 Software Development Kit (SDK)."

The Energy Harvesting Bluetooth Low Energy Switch is compatible with the ON Semiconductor IoT Development Kit and Bluetooth Low Energy IoT Development Kit, which include a comprehensive portfolio of sensors, connectivity and actuator devices.

Bluetooth IoT Development Kit (B-IDK)

With optimized power consumption and easy connectivity to smartphones, Bluetooth® Low Energy is the preferred protocol for short-range connected devices including wearables, medical devices, asset trackers, beacons and various smart home devices.

Built on the industry's lowest power Bluetooth 5 certified SoC, RSL10, the B-IDK is a configurable node-to-cloud development platform for Bluetooth Low Energy applications. The B-IDK features modular hardware comprised of a wide selection of sensors and actuators.

The development software includes a CMSIS pack that contains sample code for several use cases and detailed documentation. In addition to controlling the hardware, the accompanying mobile app allows publishing and subscribing (MQTT) of sensor and actuator data from several popular cloud services.

Key Features

  • Industry's Lowest Power Bluetooth 5 radio
  • 5nW Deep Sleep
  • 7mW Peak Receiving
  • Configurable mobile application supporting cloud connectivity
  • Compatible with AWS, Azure, Bluemix or custom cloud services
  • Ready-to-Use Sample Code
  • Easily Connect to Other IoT Development Kit Shield Boards
  • Complete range of options for sensing (proximity, motion, touch), and control (dual LED, stepper motor, brushless dc)