TY - JOUR
T1 - A multifrequency magnetic induction tomography system using planar gradiometers: data collection and calibration
AU - Rosell, Javier
AU - Merwa, Robert
AU - Brunner, Patricia
AU - Scharfetter, Hermann
PY - 2006/5/1
Y1 - 2006/5/1
N2 - We developed a 14-channel multifrequency magnetic induction tomography system (MF-MIT) for biomedical applications. The excitation field is produced by a single coil and 14 planar gradiometers are used for signal detection. The object under measurement was rotated (16 steps per turn) to obtain a full data set for image reconstruction. We make measurements at frequencies from 50 kHz to 1 MHz using a single frequency excitation signal or a multifrequency signal containing several frequencies in this range. We used two acquisition boards giving a total of eight synchronous channels at a sample rate of 5 MS s -1 per channel. The real and imaginary parts of ΔB/B 0 were calculated using coherent demodulation at all injected frequencies. Calibration, averaging and drift cancellation techniques were used before image reconstruction. A plastic tank filled with saline (D = 19 cm) and with conductive and/or paramagnetic perturbations was measured for calibration and test purposes. We used a FEM model and an eddy current solver to evaluate the experimental results and to reconstruct the images. Measured equivalent input noise voltage for each channel was 2 nV Hz-1/2. Using coherent demodulation, with an integration time of 20 ms, the measured STD for the magnitude was 7 nVrms (close to the theoretical value only taking into account the amplifier's thermal noise). For long acquisition times the drift in the signal produced a bigger effect than the input noise (typical STD was 10 nV with a maximum of 35 nV at one channel) but this effect was reduced using a drift cancellation technique based on averaging. We were able to image a 2 S m-1 agar sphere (D = 4 cm) inside the tank filled with saline of 1 S m-1.
AB - We developed a 14-channel multifrequency magnetic induction tomography system (MF-MIT) for biomedical applications. The excitation field is produced by a single coil and 14 planar gradiometers are used for signal detection. The object under measurement was rotated (16 steps per turn) to obtain a full data set for image reconstruction. We make measurements at frequencies from 50 kHz to 1 MHz using a single frequency excitation signal or a multifrequency signal containing several frequencies in this range. We used two acquisition boards giving a total of eight synchronous channels at a sample rate of 5 MS s -1 per channel. The real and imaginary parts of ΔB/B 0 were calculated using coherent demodulation at all injected frequencies. Calibration, averaging and drift cancellation techniques were used before image reconstruction. A plastic tank filled with saline (D = 19 cm) and with conductive and/or paramagnetic perturbations was measured for calibration and test purposes. We used a FEM model and an eddy current solver to evaluate the experimental results and to reconstruct the images. Measured equivalent input noise voltage for each channel was 2 nV Hz-1/2. Using coherent demodulation, with an integration time of 20 ms, the measured STD for the magnitude was 7 nVrms (close to the theoretical value only taking into account the amplifier's thermal noise). For long acquisition times the drift in the signal produced a bigger effect than the input noise (typical STD was 10 nV with a maximum of 35 nV at one channel) but this effect was reduced using a drift cancellation technique based on averaging. We were able to image a 2 S m-1 agar sphere (D = 4 cm) inside the tank filled with saline of 1 S m-1.
KW - Eddy currents
KW - Magnetic induction spectroscopy
KW - Tomography
UR - http://www.scopus.com/inward/record.url?scp=33745163572&partnerID=8YFLogxK
U2 - 10.1088/0967-3334/27/5/S23
DO - 10.1088/0967-3334/27/5/S23
M3 - Article
SN - 0967-3334
VL - 27
SP - S271-S280
JO - Physiological Measurement
JF - Physiological Measurement
IS - 5
M1 - S23
ER -