Design Considerations for RF Energy Harvesting Devices Harry Ostaffe Director, Marketing & Business Development 1
Overview RF energy is generally very low Direct-power at close range to a transmitter Energy accumulation for longer range Simple battery-recharge possible System level approach needed for optimal implementation 2
Key System Elements Harvester Antenna Storage MCU Sensors Radio Comm. Protocol Power Receiving Antenna RF-DC Energy Storage MCU Sensors Communication Antenna Radio 3
Operation System Parameters continuous vs. intermittent RF power source distance, power, frequency Receiving antenna size, performance (gain) Operating voltage Energy Storage Sensors (active, passive) 4
Key RF Harvesting Characteristics Peak Efficiency Efficiency Range Frequency Range Sensitivity Output Voltage Performance Consistency Implementation Scalability 5
What makes an RF harvester efficient? RF Matching Harvester is non-linear Proper loading (DC match) Generally requires a specific discrete or emulated resistance Correct frequency Deviation results in significantly reduced efficiency 6
RF Matching Techniques Rectenna (Rectifying Antenna) No matching network, No matching loss (assuming lossless antenna dielectric) Difficult to measure diode complex impedance Requires specialized antenna design Standard Impedance (Powercast) Matched to 50Ω, Negligible matching loss No special RF equipment required Works with standard antennas 7
DC Matching Techniques Maximum Power Point Tracking (MPPT) Used in many other harvesting technologies Requires monitoring of the DC operating point Requires a voltage converter Uses power (some designs require battery) Powercast technology Automatically adjusts to AC and DC operating point No voltage converter required for harvesting Uses no power 8
DC Matching Technique - MPPT Example RF Harvester Efficiency Challenge Narrow operating band for each load Solution: Max. Power Point Tracking Used by other harvesting technologies Active monitoring of the operating point Drawback Available RF energy is already low Active MPPT consumes power 9
DC Matching Technique - Powercast 75 P1110 Powerharvester Receiver 915 MHz, 3V Load Efficiency (%) 70 65 60 55 50 45 40 35 30 25 20 15 10 5 Wide operating range Automatically maximizes efficiency Uses no power 0-10 -9-8 -7-6 -5-4 -3-2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Input Power (dbm) 10
Simplifying RF Design Data Custom Design Drop-In Modules Power 11
Battery-Free Sensor Module Designed for Low-Power RF Harvesting Module Components & Features Powercast P2110 Powerharvester Receiver MCU: Microchip PIC24 XLP Radio module: Microchip MRF24 (802.15.4) System power: 3.3V Capacitor: 50mF (as low as 3300uF) Discrete sensors: Temp, Humidity, Light Wireless protocol: MiWi P2P RF Powerharvester Radio module Capacitor Sensors Temp/Humidity/Light Microcontroller 12
System Operation Accumulate energy in capacitor Power MCU upon reaching charge threshold Power and read sensors Measure RSSI Format data packet Transmit data packet (broadcast-only) Turn off power (go dormant) Components only powered when needed 13
Sensor Module System Voltage RESET Regulated Output Voltage 3.3V 0V Vmin Vmax Capacitor Voltage GND V MAX V MIN RESET Capacitor Voltage Vmax= 1.25V Vmin= 1.05V Power Output Sensor Active Sensor Inactive Zero Stand-By Power 14
P2110 Powerharvester Receiver Pin Configuration NC 1 14 NC 60 GND 2 13 D OUT 55 RF IN 3 12 V OUT 50 GND D SET 4 5 P2110 11 10 GND V SET 45 40 INT RESET 6 7 XXXXXX Functional Block Diagram 9 8 NC V CAP Efficiency (%) 35 30 25 20 15 10 5 915MHz 868MHz 950MHz 0-12 -11-10 -9-8 -7-6 -5-4 -3-2 -1 0 1 2 3 4 5 6 7 8 9 10 11 Input Power (dbm) Measured at 1.2V charge on capacitor 15
Receiving Antenna 2 7 915 MHz center frequency Directional Pattern (122 horizontal, 68 vertical) Gain = 6.1 dbi FR4 material Front Side Antenna included with Powercast evaluation boards 16
Powercaster Transmitter 6.25 width 915 MHz center freq. 6.75 height DSSS modulation 4 Watts EIRP 1.63 depth Directional Antenna 17
Complete Demo System 2.4 GHz MRF24J40MA 915 MHz Power nanowatt XLP 16-bit Transmitter Sensor Modules Data Receiver 18
Battery-Free Sensor Module Performance 120 4W EIRP Power Transmitter Patch RX Antenna G = 6.1dBi 100 Time between Packets (s) 80 60 40 20 0 0 5 10 15 20 25 30 35 40 45 Distance (ft) 19
Conclusion Optimal performance results from system design that focuses on minimizing power Every component must be selected based on power consumption Wireless protocol must also be implemented to minimize power consumption Reduction in power consumption and operating voltages will increase range expand applications. 20
Questions Harry Ostaffe +1 412-923-4774 harry.ostaffe@powercastco.com 21