The list of results beyond the state of the art is given next:
- 1Fr motor: thinnest electric motor, Outer Diameter < 400 μm, Length < 800 μm, Speed > 27 krpm, Torque density > 298 Nm/m3, Power consumption < 4.8 mW, compatible with wireless powering.
- Wireless Power Transfer ASPAT-based rectenna, 1 x 0.6 x 5 mm, 1.175 GHz, Unique Gain/Size ratio, Output Power > 4 mW under 550 V/m of incident electric field. In-body tested. ICNIRP compliant.
- 3Fr motor: high torque stepper micromotor, Outer Diameter < 1000 μm, Length < 800 μm, Minimum step angle < 1.8 °, Torque density > 1050 Nm/m3, tethering powering.
- Double Thrust Ball Microbearing, Smallest Ball Bearing, Diameter < 800 μm, Thickness < 400 μm, Rolling Resistant Coefficient < 0.008 for loads 150 – 1500 mN.
- SmCo thick micromagnet manufacturing process, smallest SmCo micromagnet, Size and Thickness < 100 μm, Br > 1.1 T, Hcb > 850 kA/m, Magnetic Product > N30.
- LIGA microfabrication process to develop complex ferromagnetic mesoscopic-sized components with high aspect ratios and micrometric accuracy.
- Ferromagnetic yoke made in FeCo + copper wire windings, 4 layers, > 16 turns, low resistance, low impedance.
- Multilayered microcoils windings up to 5 layers, > 25 turns, Outer Diameter < 150 μm, Current Density > 600 A/mm2 in room temperature and ambient pressure.
- NdFeB micro-sized bonded permanent magnets for integration in microdevices, Br > 0.4 T, Hc > 956 kA/m, Size = 100-1000 μm.
- NdFeB N30 hollowed micromagnets, Outer Diameter < 220 μm, Inner Diameter >100 μm, Height < 400 μm.
- Pr-Fe-B Thin films prepared by sputtering.
- Multipolar micrometric magnetic rotors, Nº of Dipoles > 11, Diameter < 800 μm, Quality > N30.
- Microassembly and bonding process for micromotors, Diameter < 900 μm, Size of parts < 300 μm.
- Ultrathin Flexible High Gain Helical Antenna for In-Body Medical Applications, Outer Diameter < 400 μm, Resonance 4.7 GHz, S11 = -25.1 dB, Gain = -4.7 dBi.
- Miniaturized Archimedean antennas for WPT, Outer Diameter < 1.1 mm, Thickness < 0.52 mm, Resonance 4.9 GHz.
UWIPOM2 will constitute the key element for the foundation of micro-robotics technology for health applications but also for other fields like nano-satellites, security, mechatronics or micro-electronics. Not only high power-density allows opening this new road-map, but also, as UWIPOM2 based micro-robots will follow similar macroscopic design, similar strategies of control and automation can be directly applicable. Mechatronics engineers will be able to design any type of micro-machines operating inside the body with minimally invasive accesses and wireless powered.