Evaluation of a MEMS based theft detection circuit for RFID labels Damith Ranasinghe and Peter H. Cole 10 May 2005 Microelectronic Technologies For The New Millennium 1
RFID system C o n t r o l l e r T r a n s m i t t e r R e c e i v e r The black spot L a b e l Passive labels have no power source but obtain power from the incident RF signal. Active Tags have an on board power source. They may backscatter a reply or may be independent reply generating labels The Auto-ID Laboratory 2
Active RFID labels B Backscatter labels. E = - t Operating range of tens of meters. D H = J + Battery used only to power logic circuits. D = ρ t Independent reply generating labels. B = 0 Range of several hundred meters. Battery is used for transmitting and powering the logic circuits Power conservation is an important issue. Labels should be turned off when not interrogated. Life time of the label should commensurate the shelf life of the labeled commodity. Need to create a solution that addresses Theft detection Power conservation This paper considers Active labels operating in the UHF ISM band. 902-926 MHz (FCC Regulation in the USA). The Auto-ID Laboratory 3
Theft detection system M ag ne t Piez oe le ctric m aterial F w P h F t p t m The proposed theft detection circuit is a zero power turn-on circuit for active RFID labels that will rely on generating a voltage of the order of 1V that can turn a CMOS transistor from fully off to fully on when triggered by a low frequency large volume magnetic field. The Auto-ID Laboratory 4
Screaming corridor The low frequency large volume magnetic field provides the trigger for the MEMS circuit. Such a field can be setup in and around the vicinity of a large corridor exit to turn the MEMS theft circuitry on when a thief attempts to flee with stolen The Auto-ID Laboratory goods. 5
Large volume LF field Trigger field Use of an unlicensed frequency in the LF spectrum. Frequency large enough to prevent false triggering. Consider the use of 130 khz trigger frequency. Need to consider practically achievable magnetic fields at 130 khz. Coil diameter 3m, coil wire diameter 10 mm, Power 50 W, 0-10 2 a 0 z -20 H ( z ) z -30-40 Ia H z ( z) = 2 + 2 2 2 3/ 2 ( a z ) -50-60 0 0.5 1 1.5 2 2.5 3 3.5 4 Distance z normalised with respect to coil radius The Auto-ID Laboratory 6
Magneto-electroacoustic energy conversion Requires a 1 V from the MEMS device Approximate voltage required to turn on a FET FET will form a switch that will activate the theft detection logic In case of a theft the label will alter the near by readers and transmit a beacon at full power for the duration of the battery. Allows the thief to be tracked. The power generated from the MEMS device is rectified and used to turn on the theft detection circuit. q θ = C C 11P 21P C C 12P 22P φ τ The Auto-ID Laboratory 7
Magneto-electroacoustic energy conversion RMS voltage available to turn on a FET V TO = k 2 2 2 2 2 2 eff Qm ( Mvµ 0) H C22S CJC22eff 2 rk k eff = 2 2 ( 1+ r) k ( 1+ r) 2 k C22eff = 1 C22P 2 1+ r is the effective electromechanical coupling factor of the MEMS structure. is the effective compliance of the structure.. Where Cj is the junction capacitance of the diode presented to the MEMS device. r = CJ /C 11.. H is the magnetic field strength. Q is the quality factor of mechanical resonance. M is the remnant magnetisation constant. v is the volume of the magnetic structure. The Auto-ID Laboratory 8
Practical evaluation Evaluate the feasibility of the structure PZT piezoelectric material Shear coupling coefficient of 0.69 Frequency constant of 1000 Hzm Height, h = 7mm PZT compliance of 30 10-12 m 2 N -1. Resonance frequency of the piezoelectric structure as a function of its thickness The Auto-ID Laboratory 9
AUTO-ID LABS Practical evaluation 1.6 1.4 1.2 V ERP (V) 1 0.8 0.6 0.4 0.2 0 6 5 6 4-3 x 10 5 3 4 3 2 2 1 Piezoelectric width (m) Effect of the piezoelectric structure dimensions on VTO at ½ meters from the screaming corridor 0 0 Thickness of the magnet (m) Effect of the magnetic structure dimensions on VTO at ½ meters from the screaming corridor The Auto-ID Laboratory -3 x 10 1 10
Practical evaluation Optimal size of the structure for maximum sensitivity w = 5 mm, t p = 2 mm, t m = 2 mm and h = 7.5 mm. Turn on range of the theft detection label measured from a screaming corridor Turn on range of the theft detection label measured from a screaming corridor when the structure is off mechanical resonance The Auto-ID Laboratory 11
Conclusions Sufficient energy transfer is possible and thus a feasible solution. Meets the demands of a high performance theft detecting RFID label for high-end goods. Minimizes power consumption Improved lifetime for the label Mechanical Q of the structure is high Narrow band resonance at 130 khz prevents false turn-on from stray magnetic fields. Good voltage magnification Future work will involve the examination of other possible structures and the interplay between the electrode capacitance and the piezoelectric capacitance. Simulation of the mechanical structure to confirm the results obtained from the analytical method. The Auto-ID Laboratory 12