Jose Lasa
ABSTRACT
Transconductor-capacitor or simply GmC filters and amplifiers are an attractive option for the design of biomedical circuits because of their extremely low power consumption. GmC filters for the analog processing of sensed outputs and biomedical signals, can be realized consuming as little as a few tens or hundreds nA current (a negligible power budget for a primary battery). Minimum or no external components are required, but there is always uncertainty in the transfer function of the filter. This paper shows the development of fully integrated GmC filters for medical applications, emphasizing on the variability of their response with technology parameters that may change from an integrated circuit to another or from a fabrication batch to another. GmC filters, amplifiers and rectifiers will be presented. Two examples are discussed: a GmC band pass amplifier for a piezoelectric accelerometer to estimate physical activity and a robust GmC cardiac sensing channel.
- L. Lentola, A. Mozzi, A. Neviani and A. Baschirotto, "A 1μA front end for pacemaker atrial sensing channels with early sensing capacity." IEEE Trans. Circuits and Systems -- II, 50(8), pp397--403, 2003.Google Scholar
Cross Ref
- Wong, L. S. Y., et al. "A very low power CMOS mixed signal IC for implantable pacemaker applications", IEEE JSSCS, 39(12), pp.2446--2456, Dec.2004.Google Scholar
- R. Schaumann, "Continuous-Time Integrated Circuits" Proc. IEEE, vol.136, Pt.G, pp184--190, Aug. 1989.Google Scholar
- C.D. Salthouse, R. Sarpeshkar, "A Practical Micropwer Programmable Band-pass filter for use in Bionic Ears", IEEE JSSC, Vol.38, nº1, pp.63--70, Jan 2003.Google Scholar
- J. Silva-Martinez, J. Salcedo-Suñer, "IC Voltage to Current Transconducters with Very Small Transconductance" Analog Integrated Circuits and Signal Proc., 13, pp.285--293,1997. Google ScholarDigital Library
- P. Corbishley, E. Rodriguez-Villegas, "A Nanopower Band-pass Filter for Detection of an Acoustic Signal in a Wearnable Breathing Detector" IEEE Trans. on Biomedical Circuits & Systems, 1(3), pp.163--171, September 2007.Google ScholarCross Ref
- A. Arnaud, C. Galup-Montoro, "Fully integrated signal conditioning of an accelerometer for implantable pacemakers" Analog Integrated Circuits & Signal Proc. 49, pp.313--321. Dec.2006. Google ScholarDigital Library
- A. Aranud, C. Galup-Montoro, "Pico A/V range CMOS transconductors using series-parallel current division", Electronic Letters, v.39,nº18, p.1295--1296, September 2003.Google Scholar
- ENDEVCO, "Model 12M1 Piezoelectric Accelerometer - Datasheet". http://www.endevco.comGoogle Scholar
- D. Linden, T.B. Reddy(eds.), Handbook of batteries, 3d ed., McGraw Hill, ISBN-0-07-135978-8,2002.Google Scholar
- E. Camacho-Galeano et al, "A 2nW 1.1V Self Biased Current Reference in CMOS Technology", IEEE Trans. On Circuits and Systems II: Express Briefs, 52(2), pp.61--65, Feb. 2005.Google ScholarCross Ref
- CELENEC Standard EN45502 2-1.Google Scholar
- D. Prutchi, M. Norris, Design and Development of Medical Electronic Instrumentation: A Practical Perspective of the Design, Construction and Test of Medical Devices, Wiley 2004, ISBN 0471676233.Google Scholar
- F. Silveira, P. Jespers, Low Power Analog CMOS for Cardiac Pacemaker: Design and Optimization in Bulk and SOI Technologies, Springer 2010, ISBN 14419554198.Google Scholar
- J. Lasa, M.Miguez, A. Arnaud, "A fully integrated preamplifier for cardiac sensing in a HVCMOS technology". Proc. 32nd IEEE Engineering in Medicine and Biology Conference, Sep. 2010.Google Scholar
- LT-Spice: Http://www.linear.com/designtools/software/Google Scholar
Index Terms
- On the design of micro power practical GmC filters for biomedical applications
Recommendations
Step down DC/DC converter for micro-power medical applications
In this work, a micropower step down DC/DC converter aimed at reducing the supply voltage in implantable medical devices is presented. The circuit was designed and fabricated in a 0.6 µm technology. The DC/DC converter was tested for a wide range of ...
A monolithic based NIRS front-end wireless sensor
This paper concerns a novel analog front-end of a wireless brain oxymeter smart sensoring instrument based on near-infrared spectroreflectometry (NIRS). The NIRS sensor makes use of dynamic threshold transistors (DTMOS) for low voltage (1V), low power ...
Inverter-based low-noise, 150 µW single-ended to differential SC-VGAs for second harmonic cardiac ultrasound imaging probes
This paper presents two inverter-based low-noise, low-power, single-ended to differential switched-capacitor variable gain amplifiers (SC-VGAs) for 2---6-MHz second harmonic cardiac ultrasound imaging probes fabricated with 0.18 µm complementary metal---...
Comments