AdaptiveEnergy Announces Wireless, Remote Sensing Energy Harvesting Solution Based On TI Ultra-Low Power Technology

Claiming to have demonstrated the advantages of energy harvesting and radio frequency (RF) technology for wireless sensing, monitoring or ambient intelligence, AdaptivEnergy announced that it has developed a demonstration kit using Joule-Thief™ technology to harvest energy and power Texas Instruments Inc.’s (TI) ultra-low power MSP430 microcontroller (MCU) and RF technology to collect data, control the operation of a system or send sensed data to central collection sites.

The Joule-Thief energy harvesting device is based on AdaptivEnergy’s Ruggedized Laminated Piezo (RLP®) technology, which enables compact energy harvesting modules to power applications such as wireless sensors. These wireless sensors could be used to gather ambient intelligence to detect and report critical conditions in factories, automobiles, office buildings, homes and other environments – all without wiring or batteries.

According to Darnell Group, the potential worldwide market for energy harvesting solutions used in wireless sensor systems could reach approximately 164 million units by 2013, a compound annual growth rate of nearly 65%. Energy harvesting is an important emerging area of low power technology that can provide energy not only for large-scale needs through wind and solar systems, but also for smaller-scale needs such as sensor networks, utilizing the vibrations inherent in structures, vehicles and machinery to create power, or harvest energy, that can drive sensors while eliminating the need for wires and batteries. For example, Joule-Thief-enabled sensors could harvest energy from the rumbling vibrations created by traffic on a bridge, then send that data from all the wireless sensors on the bridge to a collection point where it would be analyzed to monitor structural soundness.

Joule-Thief technology combines AdaptivEnergy’s stressed-biased RLP energy harvesting beam that converts vibrations or movement into usable electric energy. The RLP Smart Energy Beam is said to allow up to ten times more strain to be applied to the piezoceramic than competing piezoelectric energy harvesting devices, creating more converted electric power for system use. In addition to directly sensing movement, the versatile design accepts inputs from external sensing elements that can help detect strain in bridges and high-rise buildings, equipment fatigue in factories, excessive temperatures, the presence of dangerous chemicals, unsafe events in automobiles and a variety of other environmental conditions.

Complementing the RLP Smart Energy Beam and collection electronics is active intelligence and communications based on a chipset consisting of an MSP430F2274 microcontroller and a CC2500 RF transceiver, which allows the Joule-Thief design to gain as much processing and transmission as possible from the charge stored in a capacitor. With leading low power consumption in active and standby modes, the MSP430 microcontroller provides a fast wake-up time of less than a microsecond for a preferable low power/high performance solution.

System-on-chip (SoC) integration of peripherals in the MSP430 microcontroller such as analog-to-digital converters (ADC), timers, comparators and a variety of memory configurations helped AdaptivEnergy save space and board costs while enabling them to build a maintenance-free wireless sensor suitable for a wide range of ambient intelligence applications. TI’s CC2500 RF transceivers operate in the 2.4-GHz range, making them well-suited for reliable, low-cost digital wireless applications.