prof.dr.ir. G.C.M. Meijer

Guest
Electronic Instrumentation (EI), Department of Microelectronics

Biography

Gerard C.M. Meijer received his M.Sc. and Ph.D. degrees in Electrical Engineering from the Delft University of Technology, Delft, The Netherlands, in 1972 and 1982, respectively. Since 1972 he has been a member of the Research and teaching staff of Delft University of Technology, where he is a professor, engaged in research and teaching on Analogue Electronics and Electronic Instrumentation. Since 1984, he has been consultant for industrial companies and research institutes. In 1996 he co-founded the company SensArt, where he is consultant in the field of sensor systems. In 1999 the Dutch Technology Foundation STW awarded him with the honouree degree �Simon StevinMeester� and in 2001 he was awarded the Anthony van Leeuwenhoek chair at TUDelft. In addition to many journal and conference papers, Meijer is also author and editor of books in the field of sensor systems, published by IOP, Kluwer, Springer and Wiley.

Publications

  1. Description of a low-field MRI scanner based on permanent magnets
    M. de Leeuw den Bouter; D. Gecmen; A. Meijer; D. de Gans; L. Middelplaats; R. Remis; M. van Gijzen;
    In Proceedings of the 10th Colour and Visual Computing Symposium 2020 (CVCS 2020),
    Gjovik, (Norway), CVCS 2020, September 2020.
    document

  2. Method and device for measuring dielectrics in fluids
    J. Hillebrand; M.J.J. Mayer; G.C.M. Meijer; L.C.P.M. de Smet E.J.R. Sudhölter;
    Patent, Netherlands NL1042400B1, April 2019.
    Abstract: ... The present invention relates to a method and device for measuring dielectrics in fluids, such as water, characterized by a first printed circuit board (PCB), a first conductor on the first side of said first PCB, a second conductor on the second side of said first PCB, a first polymer affinity layer and a second polymer affinity layer on top of the first and second sides of the first PCB respectively, a second PCB equipped with holes and a first conductor plate placed on top of the first affinity layer and a third PCB equipped with holes and a second conductor plate placed on top of the second affinity layer. The result is a sensor consisting of a first PCB sandwiched between the first and second polymer affinity layers and between the second and third PCBs. The sensor is placed in the fluid under investigation and the polymer affinity layers in the sensor absorb chemical compounds and / or ions present in the fluid. At lower frequencies the sensor acts as a capacitive sensor, where absorbed compounds can be characterized by changes in the capacitor value and in the losses. At higher frequencies, the sensor behaves electrically as a stub resonator, the absorbed compounds and / or ions can be characterized or identified through impedance spectroscopy.

  3. Design of a temperature sensor with optimized noise-power performance
    A. Heidari; G. Wang; Motahareh Abdollahpour; G.C.M. Meijer;
    Sensors and Actuators A: Physical,
    Volume 282, pp. 79--89, October 2018. DOI: 10.1016/j.sna.2018.09.006
    Abstract: ... This paper presents the design aspect of a BJT-based temperature sensor implemented in standard CMOS technology that is optimized for its noise-power performance. The interface electronics of the sensor consists of a continuous-time duty-cycle modulator, where a capacitor is periodically charged and discharged, with two temperature-dependent current sources, between two thresholds determined by a Schmitt trigger. In order to optimize the noise properties of the sensor, the major noise sources have been analyzed and optimized using target specifications of the manufacturer. Experimental results are in agreement with those of simulations and analytical calculations. The sensor has been implemented in 0.7μm CMOS technology. At 3.3V supply, the measured temperature resolution amounts to 3mK for a measurement time of 1.8ms. The test results show that a Resolution Figure of Merit (RFoM) of 3.2pJK² has been achieved in this design, which is the best reported result for BJT-based temperature sensors in the market.

  4. Smart Sensors and MEMS: Intelligent Sensing Devices and Microsystems for Industrial Applications. (Ch 3: Smart temperature sensors and temperature-sensor systems)
    Gerard C.M. Meijer; Guijie Wang; Ali Heidary;
    Stoyan Nihtianov; Antonio Luque (Ed.);
    Woodhead Publishing, , pp. 57--85, 2018. ISBN:978-0-08-102055-5. DOI: 10.1016/C2016-0-01622-4

  5. An accurate BJT-based CMOS temperature sensor with Duty-Cycle-Modulated output
    G. Wang; A. Heidari; K.A.A. Makinwa; G.C.M. Meijer;
    IEEE Transactions on Industrial Electronics,
    Volume 64, 2 2017. DOI: 10.1109/tie.2016.2614273

  6. An accurate BJT-based CMOS temperature sensor with Duty-Cycle-Modulated output
    G. Wang; A. Heidari; K.A.A. Makinwa; G.C.M. Meijer;
    IEEE Transactions on Industrial Electronics,
    Volume 64, Issue 2, pp. 1572-1580, 2 2017. DOI: 10.1109/tie.2016.2614273

  7. Functional and Molecular Characterization of Mouse Gata2-Independent Hematopoietic Progenitors
    Polynikis Kaimakis*; Emma de Pater*; Christina Eich*; Parham Solaimani Kartalaei; Mari-Liis Kauts; Chris S. Vink; Reinier van der Linden; Martine Jaegle; Tomomasa Yokomizo; Dies Meijer; Elaine Dzierzak;
    Blood,
    Volume 127, Issue 11, pp. 1426--1437, March 2016. DOI: 10.1182/blood-2015-10-673749
    document

  8. Water-enhanced guarding of polymer-coated IDE platforms as a key mechanism for achieving response immunity towards parasitic coupling events
    J. Staginus; Z.Y. Chang; E.J.R. Sudholter; LC.P.M. de Smet; G.C.M. Meijer;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 234, pp. 239-247, 2015. Available online 10-9-2015.

  9. Smart sensor systems: Emerging technologies and applications
    G. Meijer; K. Makinwa; M. Pertijs;
    John Wiley \& Sons, , 2014.
    Abstract: ... With contributions from an internationally-renowned group of experts, this book uses a multidisciplinary approach to review recent developments in the field of smart sensor systems, covering important system and design aspects. It examines topics over the whole range of sensor technology from the theory and constraints of basic elements, physics and electronics, up to the level of application-orientated issues.

    document

  10. Dedicated Impedance-Sensor Systems
    G. Meijer; X. Li; B. Iliev; G. Pop; Z. Y. Chang; S. Nihtianov; Z. Tan; A. Heidari; M. Pertijs;
    In Smart Sensor Systems: Emerging Technologies and Applications,
    John Wiley \& Sons, May 2014.
    Abstract: ... Impedance sensors can be defined as being a set of electrodes which can be used to measure electrical properties of materials or structures. Once these properties are known, it appears that the features of measurements performed with such sensors depend for a large part on the properties of the material or structure to be characterized and only partly on the characteristics of the electrodes. The electrical properties of the sensor in its application can be modeled with passive elements in equivalent electrical circuits. The challenging task for the designer is to make such a sensor system sensitive for the measurands and to obtain immunity for other parameters. In this chapter, we consider impedance sensors to be sensors in a certain measurement environment, and that in the electric model presentation of this setup there is at least one resistive or one reactive component of interest which has to be measured.

    document

  11. A BJT-based CMOS temperature sensor with a 3.6pJ·K2-resolution FoM
    A. Heidary; Guijie Wang; K.A.A. Makinwa; G.C.M. Meijer;
    In LC Fujino; {Anderson et al}, J (Ed.), Digest of Technical Papers - 2014 IEEE International Solid-State Circuits Conference,
    IEEE, pp. 224-225, 2014. Harvest Session 12. Sensors, Mems, and Displays 12.8.

  12. A CMOS Smart Temperature Sensor with duty-cycle-modulated output
    Guijie Wang; A. Heidari; G.C.M. Meijer;
    In s.n (Ed.), Proceedings of Sense of Contact 2014,
    s.n., pp. 1-2, 2014.

  13. Capacitive response of PDMS-coated IDE platforms directly exposed to aqueous solutions containing volatile organic compounds
    J. Staginus; I.M. Aerts; Z.Y. Chang; G.C.M. Meijer; LC.P.M. de Smet; E.J.R. Sudholter;
    Sensors and Actuators B: Chemical: international journal devoted to research and development of physical and chemical transducers,
    Volume 184, pp. 130-142, 2013.

  14. A Low-Power CMOS Smart Temperature Sensor with a Batch-Calibrated Inaccuracy of ±0.25°C (±3σ) from -70°C to 130°C
    A. Aita; M. Pertijs; K. Makinwa; J. Huijsing; G. Meijer;
    IEEE Sensors Journal,
    Volume 13, Issue 5, pp. 1840‒1848, May 2013. DOI: 10.1109/JSEN.2013.2244033
    Abstract: ... In this paper, a low-power CMOS smart temperature sensor is presented. The temperature information extracted using substrate PNP transistors is digitized with a resolution of 0.03°C using a precision switched-capacitor (SC) incremental ΔΣ A/D converter. After batch calibration, an inaccuracy of ±0.25°C (±3) from -70°C to 130°C is obtained. This represents a two-fold improvement compared to the state-of-the-art. After individual calibration at room temperature, an inaccuracy better than ±0.1°C over the military temperature range is obtained, which is in-line with the state-of-the-art. This performance is achieved at a power consumption of 65 μW during a measurement time of 100 ms, by optimizing the power/inaccuracy tradeoffs, and by employing a clock frequency proportional to absolute temperature. The latter ensures accurate settling of the SC input stage at low temperatures, and reduces the effects of leakage currents at high temperatures.

  15. Ultra-low Energy CMOS Humidity Sensors for RFID Applications
    Z. Tan; R. Daamen; A. Humbert; Y. V. Ponomarev; Y. Chae; G. C. M. Meijer; M. A. P. Pertijs;
    In Annual Sensor Technology Workshop Sense of Contact,
    The Netherlands, April 2013. (Best Poster Award).

  16. An energy-efficient 15-bit capacitive-sensor interface based on period modulation
    Z. Tan; S. H. Shalmany; G. C. M. Meijer; M. A. P. Pertijs;
    IEEE Journal of Solid-State Circuits,
    Volume 47, Issue 7, pp. 1703‒1711, July 2012. DOI: 10.1109/jssc.2012.2191212
    Abstract: ... This paper presents an energy-efficient capacitive-sensor interface with a period-modulated output signal. This interface converts the sensor capacitance to a time interval, which can be easily digitized by a simple digital counter. It is based on a relaxation oscillator consisting of an integrator and a comparator. To enable the use of a current-efficient telescopic OTA in the integrator, negative feedback loops are applied to limit the integrator's output swing. To obtain an accurate ratiometric output signal, auto-calibration is applied. This eliminates errors due to comparator delay, thus enabling the use of a low-power comparator. Based on an analysis of the stability of the negative feedback loops, it is shown how the current consumption of the interface can be traded for its ability to handle parasitic capacitors. A prototype fabricated in 0.35 μm standard CMOS technology can handle parasitic capacitors up to five times larger than the sensor capacitance. Experimental results show that it achieves 15-bit resolution and 12-bit linearity within a measurement time of 7.6 ms for sensor capacitances up to 6.8 pF, while consuming only 64 μA from a 3.3 V power supply. Compared to prior work with similar performance, this represents a significant improvement in energy efficiency.

  17. Front-end receiver electronics for a matrix transducer for 3-D transesophageal echocardiography
    Z. Yu; S. Blaak; Z. Y. Chang; J. Yao; J. G. Bosch; C. Prins; C. T. Lancee; N. de Jong; M. A. P. Pertijs; G. C. M. Meijer;
    IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control,
    Volume 59, Issue 7, pp. 1500‒1512, July 2012. DOI: 10.1109/tuffc.2012.2350
    Abstract: ... There is a clear clinical need for creating 3-D images of the heart. One promising technique is the use of transesophageal echocardiography (TEE). To enable 3-D TEE, we are developing a miniature ultrasound probe containing a matrix piezoelectric transducer with more than 2000 elements. Because a gastroscopic tube cannot accommodate the cables needed to connect all transducer elements directly to an imaging system, a major challenge is to locally reduce the number of channels, while maintaining a sufficient signal-to-noise ratio. This can be achieved by using front-end receiver electronics bonded to the transducers to provide appropriate signal conditioning in the tip of the probe. This paper presents the design of such electronics, realizing time-gain compensation (TGC) and micro-beamforming using simple, low-power circuits. Prototypes of TGC amplifiers and micro-beamforming cells have been fabricated in 0.35-μm CMOS technology. These prototype chips have been combined on a printed circuit board (PCB) to form an ultrasound-receiver system capable of reading and combining the signals of three transducer elements. Experimental results show that this design is a suitable candidate for 3-D TEE.

  18. Surface-engineered sensors: polymer-based sensors for the capacitive detection of organic water pollutants
    J. Staginus; I.M. Aerts; Z.Y. Chang; G.C.M. Meijer; LC.P.M. de Smet;
    conference, 2012. TU Delft.

  19. Dedicated impedance sensors in their applications
    G.C.M. Meijer; A. Heidary; B. Iliev; G. Pop;
    SUSU Publication Center, , pp. 14-16, 2012.

  20. Bandwidth requirements for Op-amp in temperature sensors with duty-cycle modulated output.
    S. Foruhi; M. Shahmohammadi; A. Heidary; G.C.M. Meijer; Guijie Wang;
    In {Ivanov et al}, R (Ed.), Proceedings XXI International Scientific Conference Electronics 2012,
    Technical University of Sofia, pp. 61-64, 2012.

  21. A capacitance measurement system with milliwatt power and attofarad resolution
    A. Heidary; R. Taherkhani; G.C.M. Meijer;
    In M Kamarei; P Jabehdar-Maralani (Ed.), Proceedings 2012 20th Iranian Conference on Electrical Engineering,
    IEEE, pp. 263-266, 2012. Harvest Article number: 6292365.

  22. A temperature sensor with duty-cycle-modulated output implemented CMOS technology
    Guijie Wang; A. Heidary; G.C.M. Meijer;
    In {Ivanov et al}, R (Ed.), Proceedings XXI International Scientific Conference Electronics 2012,
    Technical University of Sofia, pp. 59-60, 2012.

  23. Surface-engineered sensors: polymer-based sensors for the capacitive detection of organic pollutants in water
    J. Staginus; I.M. Aerts; Z.Y. Chang; G.C.M. Meijer; LC.P.M. de Smet; E.J.R. Sudholter;
    In s.n. (Ed.), Water, IMCS 2012 - The 14th International Meeting on Chemical Sensors,
    AMA Association, pp. 1141-1144, 2012.

  24. A 9-channel low-power receiver ASIC for 3D transesophageal echocardiography
    Z. Yu; S. Blaak; C. Prins; Z. Y. Chang; C. T. Lancée; J. G. Bosch; N. de Jong; G. C. M. Meijer; M. A. P. Pertijs;
    In Proc. IEEE International Ultrasonics Symposium (IUS),
    IEEE, pp. 2063‒2066, October 2012. DOI: 10.1109/ultsym.2012.0516
    Abstract: ... This paper presents a 9-channel low-power receiver ASIC dedicated to a matrix piezoelectric ultrasound transducer for 3D Trans-Esophageal Echocardiography (TEE). It consists of 9 low-noise amplifiers (LNAs), 9 time-gain-compensation (TGC) amplifiers and a 9:1 micro-beamformer. A prototype ASIC has been implemented in 0.35 μm CMOS technology, with a core area of 0.98 mm × 1.7 mm. It is operated at a 3.3 V supply and consumes only 0.5 mW per channel. The measured channel-to-channel mismatch is within ±1 dB. Acoustic measurements proved the micro-beamforming function of the ASIC when processing real ultrasound signals from a 3 × 3 transducer array. These promising results show that this design, after layout optimization, is suitable to be scaled up to accommodate a full matrix transducer.

  25. Ultrasound beamformer using pipeline-operated S/H delay stages and charge-mode summation
    Z. Yu; M. A. P. Pertijs; G. C. M. Meijer;
    Electronics Letters,
    Volume 47, Issue 18, pp. 1011‒1012, September 2011. DOI: 10.1049/el.2011.1786
    Abstract: ... The proposed ultrasound beamformer is based on the delay-and-sum beamforming principle. The circuit consists of several programmable delay lines. Each delay line is constructed by pipeline-operated sample-and-hold (S/H) stages with digitally-assisted delay control, which ensure delay-independent gain and good timing accuracy. The summation is realised in the charge domain using the charge-averaging method, which consumes virtually no extra die area or power. A prototype beamformer has been fabricated in a 0.35 m CMOS process to interface nine transducer elements. Measurement results show that this circuit consumes much less power and chip area than the prior art, while maintaining good accuracy and flexibility.

  26. Application challenges of capacitive sensors with floating targets
    S. Nihtianov; G.C.M. Meijer;
    In s.n. (Ed.), Proc. of the IEEE Africon,
    IEEE, pp. 1249-1254, 2011.

  27. An energy-efficient 15-bit capacitive sensor interface
    Z. Tan; M. A. P. Pertijs; G. Meijer;
    In Proc. European Solid-State Circuits Conference (ESSCIRC),
    IEEE, pp. 283‒286, September 2011. DOI: 10.1109/esscirc.2011.6044962

  28. Design and empirical investigation of capacitive human detectors with opened electrodes
    R.A. Cardenas; H.M.M. Kerkvliet; G.C.M. Meijer;
    Measurement Science and Technology,
    Volume 21, Issue 1, pp. 1-8, 2010.

  29. A flexible low power high resolution integrated interface for capacitive sensors
    A. Heidary; S. Shalmany; G.C.M. Meijer;
    In s.n (Ed.), Proceedings of IEEE ISIE 2010,
    IEEE ISIE, pp. 3347-3350, 2010.

  30. Design of a Beamformer for an Ultrasonic Matrix Transducer for 3D Transesophageal Echocardiography
    Z. Yu; S. Blaak; G. C. M. Meijer; M. A. P. Pertijs; C. T. Lancée; J. G. Bosch; C. Prins; N. de Jong;
    In Annual Sensor Technology Workshop Sense of Contact,
    The Netherlands, April 2010. (Best Poster Award).

  31. Energy-efficient capacitive sensor interface with high dynamic range
    Z. Tan; M. A. P. Pertijs; G. C. M. Meijer;
    In Annual Sensor Technology Workshop Sense of Contact,
    The Netherlands, April 2010.

  32. An interface circuit for grounded and leaky capacitive sensors
    X. Li; G.C.M. Meijer;
    In s.n (Ed.), Proceedings of ICIT 2010,
    IEEE ICIT 2010, pp. 1571-1574, 2010.

  33. A high resolution universal integrated interface for capacitive sensors
    A. Heidary; Z.Y. Chang; G.C.M. Meijer;
    In P.J. French (Ed.), Proceedings of STW-ICT conference 2010,
    STW, pp. 4-7, 2010.

  34. A programmable analog delay line for Micro-beamforming in a transesophageal ultrasound probe
    Z. Yu; M. A. P. Pertijs; G. C. M. Meijer;
    In Proc. IEEE International Conference on Solid-State and Integrated Circuit Technology (ICSICT),
    IEEE, pp. 299‒301, November 2010. DOI: 10.1109/icsict.2010.5667749

  35. Design of a low power time-gain-compensation amplifier for a 2D piezoelectric ultrasound transducer
    J. Yao; Z. Yu; M. A. P. Pertijs; G. C. M. Meijer; C. T. Lancee; J. G. Bosch; N. de Jong;
    In Proc. IEEE International Ultrasonics Symposium (IUS),
    IEEE, pp. 841‒844, October 2010. DOI: 10.1109/ultsym.2010.5935775
    Abstract: ... In this paper, a programmable time-gain compensation amplifier dedicated to a 2D piezoelectric ultrasound transducer is presented. It uses an open-loop amplifier structure consisting of a voltage-to-current converter and a current-to-voltage converter. The circuit has been designed in a standard 0.35-μm CMOS process. Simulation and measurement results show that gains of 0dB, 12dB, 26dB and 40dB can be achieved for input signals centered at 6MHz with 80dB dynamic range (100μV to 1V). The measured gain errors at 6MHz are below 1dB for all gain settings. The amplifier consumes only 130μW when driving a 250fF load.

  36. Dynamic offset canceling technique applied in the universal transducer interface
    J. ye; G.C.M. Meijer;
    Annual Journal of Electronics,
    pp. 105-108, 2009.

  37. A low power universal capacitive sensor interface for autonomous sensor applications
    Z. Tan; G.C.M. Meijer;
    s.n. (Ed.);
    Sense of Contact 2009, , pp. 1-4, 2009.

  38. A time based capacitance to digital converter with fast data acquisitions and high resolution
    A. Heidary; G.C.M. Meijer;
    s.n. (Ed.);
    Sensor and test, , pp. 297-330, 2009.

  39. An accurate readout circuit for sensors based on thermopiles/thermocouples
    Q. Jia; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), IRS2 Proceedings of SENSOR+TEST 2009 Conference,
    AMA Service, pp. 295-300, 2009.

  40. Trade-offs in the design of a universal sensor interface chip
    Q. Jia; X. Li; G.C.M. Meijer;
    In TA Tang; X Zeng; Y. Chen; H Yu (Ed.), Proceedings of 2009 IEEE 8th international conference on ASIC,
    IEEE, pp. 871-874, 2009.

  41. Dedicated impedance sensors with reduced influence of undesired physical effects
    G.C.M. Meijer; X. Li; Z.Y. Chang; B.P. Iliev;
    In s.n. (Ed.), Proceedings of ISMTII 2009,
    D. S. Rozhdestvensky Optical Society, pp. 297-301, 2009.

  42. Analysis and design of an integrated universal capacitive sensor interface
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of ISMTII 2009,
    ISMTII, pp. 268-272, 2009.

  43. A balanced design of a universal sensor interface chip
    Q. Jia; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of ISMTII 2009,
    D. S. Rozhdestvensky Optical Society, pp. 177-182, 2009.

  44. Design of a micro beamformer for a 2D piezoelectric ultrasound transducer
    S. Blaak; Z. Yu; G.C.M. Meijer; C.T. Lancee; J.G. Bosch; N. de Jong;
    In M Pappalardo (Ed.), Proceedings 2009 IEEE International Ultrasonics Symposium,
    IEEE, pp. 1338-1341, 2009. NEO.

  45. A novel interface circuit for grounded capacitive sensors with feedfrward-based active shielding
    F. Reverter; X. Li; G.C.M. Meijer;
    Measurement Science and Technology,
    Volume 19, Issue 2, pp. 1-5, 2008.

  46. Features and design constraints for an optimized SC front-end circuit for capacitive sensors with a wide dynamic range
    A. Heidary; G.C.M. Meijer;
    IEEE Journal of Solid State Circuits,
    pp. 1609-1616, 2008.

  47. An integrated interface circuit with a capacitance-to-voltage converter as front-end for grounded capacitive sensors
    A. Heidary; G.C.M. Meijer;
    Measurement Science and Technology,
    Volume 20, pp. 1-7, 2008.

  48. A high-performance interface for grounded conductivity sensors
    X. Li; G.C.M. Meijer;
    Measurement Science and Technology,
    Volume 19, Issue 11, pp. 1-7, 2008.

  49. A comparison of two-and four-electrode techniques to characterize blood impedance for the frequency range of 100 Hz to 100 MHz
    Z.Y. Chang; G.A.M. Pop; G.C.M. Meijer;
    IEEE Transactions on Biomedical Engineering,
    Volume 55, Issue 3, pp. 1247-1249, 2008.

  50. A smart integrated sensor-interface chip.DET6437,progress report IV
    Q. Jia; X. Li; G.C.M. Meijer;
    STW, , 2008.

  51. A smart integrated sensor-interface chip,DET6437,progress report V
    Q. Jia; X. Li; G.C.M. Meijer;
    STW, , 2008.

  52. Smart Sensor Systems
    Gerard C.M. Meijer;
    Gerard Meijer (Ed.);
    Wiley-Interscience, , 2008. ISBN: 978-0-470-86691-7.

  53. An adaptive front-end for grounded conductivity sensors in liquid-monitoring applications
    Q. Jia; X. Li; G.C.M. Meijer;
    s.n. (Ed.);
    Sense of Contact 2009, , pp. 1-6, 2008.

  54. A precision integrated interface circuit for thermopile based sensors
    Q. Jia; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), The IMTC IEEE 2008 proceedings,
    IEEE, pp. 1-4, 2008.

  55. An integrated interface for leaky capacitive sensor with emphasize on humidity sensor
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), The IMTC IEEE 2008 proceedings,
    I2MTC2012, pp. 1-4, 2008.

  56. Universal asynchronous sensor systems
    X. Li; G.C.M. Meijer;
    In {G.C.M. Meijer} (Ed.), Smart sensor systems,
    Wiley, pp. 10-279-311, 2008.

  57. Smart temperature sensor and temperature-sensor systems
    G.C.M. Meijer;
    In G.C.M. Meijer (Ed.), Smart sensor systems,
    Wiley, pp. 7-185-223, 2008.

  58. Interface electronics for smart sensor systems
    G.C.M. Meijer;
    In G.C.M. Meijer (Ed.), Smart sensor systems,
    Wiley, pp. 2-23-54, 2008.

  59. Capacitive sensors
    X. Li; G.C.M. Meijer;
    In {G.C.M. Meijer} (Ed.), Smart sensor systems,
    Wiley, pp. 8-225-248, 2008.

  60. Design constraints of the interface electronics for an ultrasonic matrix transducer for 3D transesophageal echocardiography
    Z. Yu; G.C.M. Meijer; C.A. Prins; N. de Jong; H. van den Bosch;
    In s.n. (Ed.), Proceedings of sense of contact X,
    Sense of Contact 2009, pp. 1-4, 2008.

  61. An adaptive front-end fo grounded conductivity sensors in liquid-monitoring applications
    Q. Jia; X. Li; G.C.M. Meijer;
    In Ru Huang; Min Yu; Xia An (Ed.), Proceedings of ICSICT,
    ICSICT, pp. 1-4, 2008.

  62. A high-performance interface for platinum temperature sensors with long-cable
    X. Li; G.C.M. Meijer;
    In {Ru Huang, Min Yu, Xia An} (Ed.), Proceedings of ICSICT,
    IEEE, pp. 1-4, 2008.

  63. New chances for asynchronous sensor interfaces
    G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of ICCDCS 2008,
    IEEE Xplore, pp. 1-6, 2008.

  64. A programmable time-gain-compensation (TGC) amplifier for medical ultrasonic echo signal processing
    Z. Yu; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of ICSICT,
    ICSIST, pp. 1-4, 2008.

  65. The interface electronics for an ultrasonic matrix transducer for 3D transephageal echocardiography
    Z. Yu; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of Electronics-ET 2008,
    Electronics 2008, pp. 19-22, 2008.

  66. Optimizing the noise performance of an integrated interface for capacitive sensors for a wide range
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings Electronics ET 2008,
    Electronics ET, pp. 9-14, 2008.

  67. Elektrische meetinrichting werkwijze en computer programmaproduct
    G.C.M. Meijer; M.A. Hilhorst;
    2008.

  68. Elektrische meetinrichting, werkwijze en computer programma product
    G.C.M. Meijer; M.A. Hilhorst;
    2008. TU Delft; 1033148; TU Delft.

  69. Extending the limits of a capacitive soil-water-content measument (U_SP_2_I_IC_T)
    Z.Y. Chang; B.P. Iliev; G.C.M. Meijer; J.F. de Groot;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 56, Issue 6, pp. 2240-2244, 2007.

  70. Liquid-level measurement system based on a remote grounded capacitive sensor (U_SP_2_I_IC_T)
    F. Reverter; X. Li; G.C.M. Meijer;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    pp. 1-8, 2007.

  71. Low-cost interface for leaky capacitive sensor with emphasize on humidity sensor
    A. Heidary; G.C.M. Meijer;
    s.n. (Ed.);
    Sense of Contact 2009, , pp. 1-6, 2007.

  72. Universal asynchronous sensor interfaces
    G.C.M. Meijer;
    In J Gajza (Ed.), Proceedings of Kongres Metrologii 2007,
    Kongres Metrologii, pp. 1-8, 2007.

  73. A sensor interface system for measuring the impedance (Cx Rx) of soil at a signal frequency of 20 MHz
    Z.Y. Chang; B.P. Iliev; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sixth IEEE Sensors Conference 2007,
    IEEE, pp. 1-4, 2007.

  74. A low-noise switched-capacitor front end for capacitive sensor
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sixth IEEE Conference on SENSORS 2007,
    IEEE, pp. 40-43, 2007.

  75. An integrated switched-capacitor front-end for capacitive sensors with a wide dynamic range
    A. Heidary; G.C.M. Meijer;
    In D Schmitt-Landsiedel; T Noll (Ed.), Proceedings of the 33rd European Solid State Circuits Conference, 2007. ESSCIRC 2007,
    IEEE, pp. 404-407, 2007.

  76. Analysis and design of CMOS smart temperature sensor (SMT) with duty-cycle modulated output
    K. kohbod; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of Electronics ET 2007,
    s.n., pp. 53-58, 2007.

  77. The noise performance of evaluation boards for a universal transducer interface with USB connecction
    Z.Y. Chang; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of Electronics ET 2007,
    s.n., pp. 47-52, 2007.

  78. Analysis and design of an integrated interface fo leaky capacitive sensors with emphasis on humidity sensors
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of Electronics ET 2007,
    s.n., pp. 41-46, 2007.

  79. A self-adaptive front-end for grounded conductivity sensors in liquid-monitoring applications
    Q. Jia; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), PRO Risc2007,
    ProRISC, pp. 42-45, 2007.

  80. A universal transducerconnection interfaces with USB
    Z.Y. Chang; G.C.M. Meijer;
    In s.n. (Ed.), A universal transducerconnection interfaces with USB,
    Sense of Contact 2009, pp. 1-4, 2007.

  81. Smart capacitive-resistive sensors
    G.C.M. Meijer; X. Li; Z. Chang; B.P. Iliev;
    In s.n. (Ed.), Proceeding of: XLII International Scientific Conference on Information, Communication and Energy Systems and Technologies - ICEST2007,
    ICEST, pp. 3-12, 2007.

  82. Stability and accuracy of active shielding for grounded capacitive sensors (U-SP-2-I-ICT)
    F. Reverter; X. Li; G.C.M. Meijer;
    Measurement Science and Technology,
    Volume 17, pp. 2884-2890, 2006.

  83. A Smart Universal Sensor-Interface Chip, Progress report 1 (U-SP-2-I-ICT)
    Q. Jia; X. Li; G.C.M. Meijer;
    STW, Volume STW report , 2006.

  84. A Smart Universal Sensor-Interface Chip,Progress report 2 (U-SP-2-I-ICT)
    Q. Jia; X. Li; G.C.M. Meijer;
    STW, Volume STW report 2 , 2006.

  85. Dedicated smart admittance-sensor systems-progress report 9/17-01-2006 (U-SP-2-I-ICT)
    B.P. Iliev; G.C.M. Meijer;
    STW, Volume STW report , 2006.

  86. Dedicated smart admittance-sensor systems-progress report-part 3 9/17-01-2006 (U-SP-2-I-ICT)
    Z.Y. Chang; B.P. Iliev; G.C.M. Meijer;
    STW, Volume STW report , 2006.

  87. Dedicated smart admittance-sensor systems-progress report-part 2 9/17-01-2006 (U-SP-2-I-ICT)
    Z.Y. Chang; B.P. Iliev; G.C.M. Meijer;
    STW, Volume STW report , 2006.

  88. In-vivo Blood Characterization system (U-SP-2-I-ICT)
    B.P. Iliev; G.C.M. Meijer; A.M. pop Gheorghe;
    G Milton; KR Fowler (Ed.);
    IEEE, , pp. 1781-1785, 2006.

  89. Catheter-based measurement system for blood analysis in vivo (U-SP-2-I-ICT)
    B.P. Iliev; A.M. pop Gheorghe; G.C.M. Meijer;
    In s.l. (Ed.), Proceedings of the The Sense of Contact VIII,
    STW, pp. 1-6, 2006.

  90. Investigations in the noise performance of the DEM SC Instrumentation Amplifier (U-SP-2-I-ICT)
    Guijie Wang; A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sense of Contact VIII,
    STW, pp. 1-6, 2006.

  91. On the performance of an active shielding for grounded capacitive sensors (U-SP-2-I-ICT)
    F. Reverter; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sense of Contact VIII,
    STW, pp. 1-6, 2006.

  92. Design and measurement of a switched -capacitor dynamic-element-matching amplifier (U-SP-2-I-ICT)
    A. Heidary; G.C.M. Meijer;
    In s.n (Ed.), Proceedings of the Sense of Contact,
    Sense of Contact 2009, pp. 1-6, 2006.

  93. Integrated interface for high-ohmic voltage generating sensors (U-SP-2-I-ICT)
    Q. Jia; X. Li; G.C.M. Meijer;
    In DE Dimitrov (Ed.), Proceedings Electronics ET2006,
    Electronics ET, pp. 1-6, 2006.

  94. Characterisation of a liquid-level measurement system based on a grounded capacitive sensor (U-SP-2-I-ICT)
    F. Reverter; X. Li; G.C.M. Meijer;
    In DE Dimitrov (Ed.), Proceedings Electronics ET 2006,
    Electronics ET, pp. 1-5, 2006.

  95. Noise Optimization of Integrated Switched-Capacitor Front-Ends with wide Dynamic Range (U-SP-2-I-ICT)
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Noise Optimization of Integrated Switched-Capacitor Front-Ends with Wide Dynamic Range,
    ProRISC, pp. 1-4, 2006.

  96. Development and Investigation of a Switched-Capacitor Dynamic-Element-Matching Amplifier (U-SP-2-I-ICT)
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings Electronics ET2006,
    Electronics ET, pp. 183-188, 2006.

  97. A low-cost and accurate interface for four-electrode conductivity sensors
    X. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 54, Issue 6, pp. 2433-2437, 2005.

  98. The noise performance of a high-speed capacitive-sensor interface based on a relaxation oscillator and a fast counter
    M. Gasulla; X. Li; G.C.M. Meijer;
    IEEE Instrumentation and Measurement Magazine,
    Volume 54, Issue 5, pp. 1934-1940, 2005.

  99. Dedicated smart admittance-sensor systems - Progress report 8/30.06.2005
    B.P. Iliev; G.C.M. Meijer;
    Technologiestichting STW, Volume STW Project, DMR.5294 , 2005. nog niet eeder opgevoerd JH.

  100. A smart universal sensor interface chip
    C. Guan; X. Li; G.C.M. Meijer;
    STW, , 2005.

  101. High-resolution low-cost ultrasonic tracking system for human-interface systems
    R.N. Aguilar Cardenas; H.M.M. Kerkvliet; G.C.M. Meijer;
    s.n. (Ed.);
    IEEE, , pp. 878-882, 2005. Editor onbekend JH.

  102. High- and low-frequency model of blood impedance
    Z.Y. Chang; B.P. Iliev; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sense of Contact 7 workshop,
    Sense of Contact 2009, pp. 1-6, 2005. Editor onbekend JH.

  103. In-vitro and in-vivo plasma resistance measurement system
    B.P. Iliev; Z.Y. Chang; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sense of Contact 7 workshop,
    Sence of Contact, pp. 1-5, 2005. Editor onbekend JH.

  104. Investigation of multi-sensor techniques for cardiac-output measurements in intensive care
    D. Tanase; B.P. Iliev; J.F.L. Goosen; Z.Y. Chang; G.A.M. Pop; J.M.M. Verwiel; C.J. Slager; L. Pakula; G.C.M. Meijer; P.J. French;
    In s.n. (Ed.), Proceedings of the 3rd annual International IEEE EMBS Special Topic Conference on Microtechnologies in Medicine and Biology,
    IEEE, pp. 122-125, 2005. Editor onbekend JH.

  105. A Two-dimensional Capacitive Human-detection system (U-SP-2-I-ICT)
    G.C.M. Meijer; R.N. Aguilar Cardenas; H.M.M. Kerkvliet;
    In s.n. (Ed.), Proceedings of the 14th International Scientific and Applied Science Conference ELECTRONICS - ET2005,
    s.n., pp. 1-6, 2005.

  106. An improved electrode structure for capacitive single-axis tilt sensors (U-SP-2-I-ICT)
    G.C.M. Meijer; H.M.M. Kerkvliet;
    In s.n. (Ed.), Proceedings of the 14th International Scientific and Applied Science Conference ELECTRONICS - ET2005,
    s.n., pp. 1-4, 2005.

  107. Single-axis tilt sensor systems
    H.M.M. Kerkvliet; G.C.M. Meijer;
    In S Tabakov (Ed.), Electronics, ET'2004 Proceedings of the conference,
    Technical University of Sofia, pp. 9-14, 2005.

  108. Extending the limits of a capacitive soil-water-content measurement
    Z.Y. Chang; B.P. Iliev; F. de Groot; G.C.M. Meijer;
    In s.n. (Ed.), IEEE, pp. 376-379, 2005. Editor onbekend JH.

  109. Capactive human-detection systems with auto-calibration
    R.N. Aguilar Cardenas; M.C. Roelofsz; H.M.M. Kerkvliet; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the 9th World Multi-Conference on Systemics, Cybernetics and Informatic, WMSCI 2005,
    ISSS, pp. 1-7, 2005. Editor onbekend JH.

  110. Resistive and capacitive single-axis tilt-sensor system
    H.M.M. Kerkvliet; G.C.M. Meijer;
    In s.n. (Ed.), 2005 sensors proceedings vol.II,
    AMA Service GmbH, pp. 243-247, 2005. Editor onbekend JH.

  111. Electronics and signal-processing techniques for smart sensor systems
    G.C.M. Meijer;
    In s.n. (Ed.), 2005 sensors proceedings vol.II,
    AMA Service GmbH, pp. 79-84, 2005. Editor onbekend JH.

  112. Measurements techniques for smart sensor interfaces implemented in CMOS technology
    G.C.M. Meijer; X. Li;
    In s.n. (Ed.), 2005 6th International Conference on ASIC Proceedings,
    IEEE, pp. 1-4, 2005. Editor onbekend JH.

  113. Trade-off in the design of speed measurements based on ultrasonic doppler effect
    R.N. Aguilar Cardenas; H.M.M. Kerkvliet; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the Sense of Contact 7 workshop,
    Sense of Contact 2009, pp. 1-7, 2005. Editor onbekend JH.

  114. Optimizing the Design of a Switched-Capacitor Dynamic-Element-Matching Amplifier
    A. Heidary; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of the annual Scientific and Applied Science conference Electronics 2005,
    Electronics ET, pp. 9-14, 2005.

  115. Catheter-based impedance measurements in the right atrium for continuously monitoring hematocrit and estimating blood viscosity changes; an in vivo feasibility study in swine
    G.A.M. Pop; Z.Y. Chang; C.J. Slager; B.J. Kooij; E.D. van Deel; L. Moraru; J. Quak; G.C.M. Meijer; DJ Duncker;
    Biosensors and Bioelectronics,
    Volume 19, Issue 12, pp. 1685-1693, 2004.

  116. Precision temperature measurement using CMOS substrate PNP transistors
    M. A. P. Pertijs; G. C. M. Meijer; J. H. Huijsing;
    IEEE Sensors Journal,
    Volume 4, Issue 3, pp. 294‒300, June 2004. DOI: 10.1109/jsen.2004.826742
    Abstract: ... This paper analyzes the nonidealities of temperature sensors based on substrate pnp transistors and shows how their influence can be minimized. It focuses on temperature measurement using the difference between the base-emitter voltages of a transistor operated at two current densities. This difference is proportional to absolute temperature (PTAT). The effects of series resistance, current-gain variation, high-level injection, and the Early effect on the accuracy of this PTAT voltage are discussed. The results of measurements made on substrate pnp transistors in a standard 0.5μm CMOS process are presented to illustrate the effects of these nonidealities. It is shown that the modeling of the PTAT voltage can be improved by taking the temperature dependency of the effective emission coefficient into account using the reverse Early effect. With this refinement, the temperature can be extracted from the measurement data with an absolute accuracy of ±0.1°C in the range of -50 to 130°C.

  117. Dedicated smart admittance-sensor systems
    B.P. Iliev; G.C.M. Meijer;
    Delft University of Technology, , 2004.

  118. Tracking system for art applications
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    s.n., Volume STW project DET 5100 , 2004.

  119. Tracking system for art applications - Third report
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    Delft University of Technology EI/ECTM, Volume STW DTE 5100 , 2004.

  120. Dedicated smart admittance-sensor systems - progress report 7
    B.P. Iliev; G.C.M. Meijer;
    TU Delft Electronic Instrumentation Laboratory, , 2004.

  121. MST-innovatie: kopen, trekken of duwen?
    G.C.M. Meijer;
    s.n., , pp. 1-2, 2004.

  122. The effect of time-constant in a thermopile-based IR detector
    A. Atghiaee; G.C.M. Meijer; C. Guan; H.M.M. Kerkvliet;
    In G.C.M. Meijer (Ed.), The sense of contact VI; sensor workshop for industry and science,
    s.n., pp. 1-6, 2004.

  123. An impedance-measurement system for electrical characerization of rockwool substrates
    B.P. Iliev; G.C.M. Meijer;
    In SIcon2004; Proceedings of the 2004 sensors for industry conference,
    IEEE, pp. 46-49, 2004. ed. is niet bekend.

  124. Electronic interface for thermopile infra-red detectors
    A. Atghiaee; G.C.M. Meijer;
    In SAFE 51dce1c4d4de41c5a2765125ca24b5e2 ProRISC 2004; Proceedings of the program for research on integrated systems and circuits,
    STW Technology Foundation, pp. 457-460, 2004. ed. is niet bekend.

  125. Electrical characterization of wetted substrates
    B.P. Iliev; M.D. Verweij; Z.Y. Chang; G.C.M. Meijer;
    In SAFE 09dcb9aaa96a4f04b679e224b65b2df8 ProRISC 2004; Proceedings of semiconductor advances for future electronics,
    STW Technology Foundation, pp. 1-4, 2004. ed. is niet bekend.

  126. Low-cost capacitive personnel detector
    R.N. Aguilar Cardenas; M.C. Roelofsz; H.M.M. Kerkvliet; R.J. van de Ven; G.C.M. Meijer;
    In Proceedings of the thirteenth international scientific and applied science conference electronics ET'2004,
    Technical University of Sofia, pp. 1-6, 2004. ed. is niet bekend.

  127. A system-level approach for the design of smart sensor interfaces
    C. Guan; X. Li; G.C.M. Meijer;
    In s.n. (Ed.), Proceedings of IEEE Sensors, 2004,
    IEEE, pp. 210-214, 2004. niet eerder opgevoerd -sb.

  128. A universal sensor interface chip design in 0.5u CMOS process
    G. Chao; G.C.M. Meijer;
    In R Huang; JJ Liou; T Hiramoto; C Claeys (Ed.), ICSICT 2004; Proceedings of the Seventh international conference on solid-state and integrated circuits technology,
    IEEE, pp. 1800-1803, 2004.

  129. A novel model of blood impedance for indirect viscosity measurement
    Z.Y. Chang; G.C.M. Meijer; G.A.M. Pop;
    In S Tabakov (Ed.), Electronics ET'2004,
    Technical University Sofia, pp. 15-21, 2004. nog niet eerder opgevoerd JH.

  130. Minimization of the mechanical-stress-induced inaccuracy in bandgap voltage reference
    F. Fruett; G.C.M. Meijer; A. Bakker;
    IEEE Journal of Solid State Circuits,
    Volume 38, Issue 7, pp. 1288-1291, 2003.

  131. A contactless capacitive angular-position sensor
    M. Gasulla; X.J. Li; G.C.M. Meijer; L. van der Ham; J.W. Spronck;
    IEEE Sensors Journal,
    Volume 3, Issue 5, pp. 607-613, 2003.

  132. Tracking system for art applications
    R.A. Cardenas; G.C.M. Meijer;
    Delft University of Technology, Volume DET 5100 , 2003.

  133. Impedance measurement system for electrical characterization of rockwool substrates
    B.P. Iliev; G.C.M. Meijer;
    Delft University of Technology - Electronic Instrumentation, Volume STW project DMR.5294 , 2003.

  134. Comparison between non-ideal and ideal-switch model in a CMOS SC integrator
    A. Atghiaee; G.C.M. Meijer; C. Guan; X.J. Li; H.M.M. Kerkvliet;
    In s.n. (Ed.), ProRISC 2003 Program for research on integrated systems and circuits,
    Stichting voor de Technische Wetenschappen, pp. 165-168, 2003. CD-ROM.

  135. Measuretechniques to improve the accuracy of smart sensor systems (invited)
    G.C.M. Meijer; X.J. Li;
    In SJ Prosser; E Lewis (Ed.), Proceedings of the twelfth conference on sensors and their applications,
    Institute of Physics, pp. 223-230, 2003.

  136. A low-cost, high-precision sensor interface for platinum temperature sensors
    A. Atghiaee; G.C.M. Meijer; X. Li; C. Guan; H.M.M. Kerkvliet;
    In A Andonova; M Hristov; P Philipov; T Takov (Ed.), MTM 2003 Seventh international symposium on microelectronics technologies and microsystems,
    Technical University of Sofia, pp. 240-243, 2003.

  137. Analysis of capacitance and linearity of Gauge characteristic of Coplanar micro-displacement sensor
    M.M. Gorbov; G.M. Gorbova; G.C.M. Meijer;
    In D Ilic; M Borsic; J Butorac (Ed.), IMEKO 2003 17th IMEKO World congress; metrology in the third millennium,
    IMEKO, pp. 1965-1968, 2003.

  138. A high-speed capacitive-sensor interface using a relaxaton oscillator and a fast counter
    M. Gasulla; X.J. Li; G.C.M. Meijer;
    In s.n. (Ed.), IMTC'03 20th IEEE instrumentation and measurement technology conference,
    IEEE, pp. 811-816, 2003. CD-ROM.

  139. A readout circuit for measuring the time-domain sensor signal
    G. Chao; G.C.M. Meijer;
    In s.n. (Ed.), IMTC 2003 Proceedings of the 20th IEEE instrumentation and measurement technology conference,
    IEEE, pp. 807-809, 2003.

  140. A switched-capacitor amplifier with dynamic element matching in the feedback network
    Guijie Wang; G.C.M. Meijer;
    In ET'2003; Proceedings of the Twlefth international scientific and applied science conference electronics,
    Technical University Sofia, pp. 13-18, 2003. nog niet eerder opgevoerd. ed. niet bekend.

  141. Droplet measurement with a capacitive sensor
    A. Atghiaee; G.C.M. Meijer; X. Li; C. Guan; H.M.M. Kerkvliet;
    In ET'2003; Proceedings of the twelth international scientific and applied science conference electronics,
    Technical University of Sofia, pp. 3-6, 2003. Nog niet opgevoerd. ed. niet bekend.

  142. Smart architecture for 3-D ultrasonic tracking system
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In ET'2003; Proceedings of the Twelfth international scientific and applied science conference electronics,
    Technical University of Sofia, pp. 7-12, 2003. nog niet eerder opgevoerd. ed. niet bekend.

  143. Capacitive smart wind sensor
    H.M.M. Kerkvliet; G.C.M. Meijer;
    In S Ovcharov; A Andonova; P Pilipov; N Gradinarov (Ed.), Electronics ET'2002,
    Technical University Sofia, pp. 129-130, 2003.

  144. A low-cost high-precision sensor interface for platinum temperature sensors
    X. Li; G.C.M. Meijer;
    In s.n. (Ed.), ASICON 2003; proceedings,
    IEEE, pp. 514-517, 2003.

  145. Electrical characterization of rockwool substrates
    B.P. Iliev; G.C.M. Meijer;
    In ET'2003; Proceedings of the Twelfth international scientific and applied science conference electronics,
    Technical University of Sofia, pp. 49-54, 2003. nog niet eerder opgevoerd. ed. niet bekend.

  146. SC interface for capacitive and voltage measurements with extended linear range
    V.P. Iordanov; G.C.M. Meijer; S.N. Nihtianov;
    In s.n. (Ed.), ProRISC 2003 Program for research on integrated systems and circuits,
    Stichting voor de Technische Wetenschappen, pp. 195-201, 2003. CD-ROM.

  147. CMOS temperature sensor and bandgap reference
    Guijie Wang; G.C.M. Meijer;
    Technical report, 2003.

  148. Universal transducer interface: specifications and applications
    X. Li; F.M.L. van de Goes; G.C.M. Meijer; R. de Boer;
    Sensor Review: the international journal of sensing for industry,
    Volume 22, Issue 1, pp. 51-56, 2002.

  149. An accurate interface for capacitive sensors
    X.J. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 51, Issue 5, pp. 935-939, 2002. niet eerder opgevoerd.

  150. Dedicated smart admittance-sensor systems (Sensor system for characterization of rockwool material)
    B.P. Iliev; G.C.M. Meijer;
    Delft University of Technology, , 2002.

  151. Dedicated smart admittance-sensor systems for the oilfield industry
    B.P. Iliev; G.C.M. Meijer;
    Delft University of Technology, , 2002. STW project.

  152. Fast and reliable capacitive transducers
    X. Li; M. Gasulla; G.C.M. Meijer;
    Delft University of Technology, Faculty ITS, , 2002. Report 8.

  153. The piezojunction effect in silicon integrated circuits and sensors
    F. Fruett; G.C.M. Meijer;
    Kluwer Academic Publishers, , 2002.

  154. Tracking system art applications: first year report
    G.C.M. Meijer; R.N. Aguilar Cardenas;
    Delft University of Technology, Faculty ITS, , 2002.

  155. Analytical calculation of the capacitance in direct imaging drum used in Océ's copy/printer machine
    G.C.M. Meijer; G.M. Gorbova; M.G. Strunsky;
    Delft University of Technology, Faculty ITS, , 2002.

  156. Fast and reliable capacitive transducers
    X. Li; M. Gasulla; G.C.M. Meijer;
    Delft University of Technology, Faculty ITS, , 2002. Report 9.

  157. A low-cost and accurate interface for conductivity sensors
    X. Li; G.C.M. Meijer;
    IEEE, , pp. 765-768, 2002. CD-Rom.

  158. 3-D position sensing using the differences in the time-of-flights from the use of multiples ultrasonic sources and to one receiver
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In Proceedings of the 17th international smposium on the 3-D analysis human movement 2002,
    Univerity of Newcastle, pp. 25-28, 2002.

  159. A contactless capacitive angular-position sensor
    M. Gasulla; X. Li; G.C.M. Meijer; L. van der Ham; J.W. Spronck;
    In IEEE sensors 2002,
    IEEE, pp. 880-884, 2002.

  160. 34.4: SC interface for capacitive measurements with extended linear range
    V.P. Iordanov; G.C.M. Meijer; S.N. Nihtianov;
    In Proceedings of IEEE sensors: first IEEE international conference on sensors. Vol. II,
    IEEE, pp. 1436-1439, 2002.

  161. Fast interface electronics for a resistive touch-screen
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In Proceedings of IEEE Sensors 2002,
    IEEE, pp. 1360-1363, 2002.

  162. P2-11: Precise calculation of capacitances of complex-shaped capacitive sensor-elements by the methods of direct field-strength determinationby the method of direct
    G.M. Gorbova; M.M. Gorbov; G.C.M. Meijer;
    In Proceedings of IEEE sensors 2002: first IEEE international conference on sensors,
    IEEE, pp. 1239-1243, 2002.

  163. SC interface with extended linear range
    V.P. Iordanov; G.C.M. Meijer; S. Nihtianov;
    In s.n. (Ed.), ET 2002 The eleventh international scientific and applied science conference. Book 1,
    Technical University, pp. 107-112, 2002. niet eerder opgevoerd.

  164. Low-drift bandgap voltage references
    F. Fruett; G.C.M. Meijer; A. Bakker;
    In A Baschirotto; P Malcovati (Ed.), ESSCIRC 2002: proceedings of the 28th European solid-state circuit conference,
    University of Bologna, pp. 383-386, 2002.

  165. Mechanical-stress effect in the base-emitter voltage of integrated bipolar transistors
    F. Fruett; G.C.M. Meijer;
    In Electronics ET'2001: The tenth international scientific and applied science conference,
    Technical University Sofia, pp. 95-98, 2002. niet eerder opgevoerd.

  166. Smart sensor interface electronics
    G.C.M. Meijer; X. Li;
    In 2002 23rd international conference on microelectronics; proceedings,
    IEEE Electron Devices Society, pp. 67-74, 2002.

  167. Low-cost ultrasonic fusion sensor for angular position
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In Proceedings of SeSens 2002,
    STW Stichting voor de Technische Wetenschappen, pp. 594-597, 2002.

  168. Non-idealities of temperature sensors using substrate PNP transistors
    M. A. P. Pertijs; G. C. M. Meijer; J. H. Huijsing;
    In Proc. IEEE Sensors Conference,
    IEEE, pp. 1018‒1023, June 2002. DOI: 10.1109/ICSENS.2002.1037251
    Abstract: ... This paper describes the nonidealities of temperature sensors based on substrate pnp transistors and shows how their influence can be minimized The effects of series resistance, current-gain variation, high-level injection and the Early effect on the accuracy of the PTAT voltage are discussed. The results of measurements made on substrate pnp transistors in a standard 0.5μm CMOS process are presented to show the effects of these nonidealities. It is shown that the modeling of the PTAT voltage can be improved by taking the temperature dependency of the effective emission coefficient into account using the reverse Early effect. With this refinement, the temperature can be extracted from the measurement data with an absolute accuracy of ±0.1°C in the range of -50°C to 130°C.

  169. The piezojunction effect in silicon sensors and circuits and its relation to piezoresistance
    J.F. Creemer; F. Fruett; G.C.M. Meijer; P.J. French;
    IEEE Sensors Journal,
    Volume 1, pp. 98-108, 2001.

  170. The piezojunction effect in silicon sensors and circuits and its relation to piezoresistance
    J.F. Creemer; F. Fruett; G.C.M. Meijer; P.J. French;
    IEEE Sensors Journal,
    Volume 1, Issue 2, pp. 98-108, 2001.

  171. A smart and accurate interface for resistive sensors
    X. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 50, Issue 6, pp. 1648-1651, 2001.

  172. An interface circuit for R-C impedance sensors with a relaxation oscillator
    S.N. Nihtianov; G.P. Shterev; B.P. Iliev; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 50, Issue 6, pp. 1563-1567, 2001.

  173. Experimental investigation of piezojunction effect in silicon and its temperature dependence
    F. Fruett; G.C.M. Meijer;
    Electronics Letters,
    Volume 37, Issue 22, pp. 1366-1367, 2001.

  174. Impedance measurements with second-order harmonic oscillator for testing food sterility
    S. Nihtianov; G.P. Shterev; N. Petrov; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 50, Issue 4, pp. 976-980, 2001.

  175. A new sensor structure using the piezojunction effect in PNP lateral transistors
    F. Fruett; G.C.M. Meijer;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 92, pp. 197-202, 2001.

  176. Temperature sensors and voltage references implemented in CMOS technology
    G.C.M. Meijer; Guijie Wang; F. Fruett;
    IEEE Sensors Journal,
    Volume 1, Issue 3, pp. 225-234, 2001.

  177. SC front-end with wide dynamic range
    G.C.M. Meijer; V.P. Jordanov;
    Electronics Letters,
    Volume 37, Issue 22, pp. 1377-1378, 2001.

  178. Fast and reliable capacitive transducers
    X. Li; G.C.M. Meijer;
    s.n., , 2001. DEL 4540.

  179. Dedicated smart admittance-sensor systems for the oilfield industry
    B. Iliev; G.C.M. Meijer;
    s.n., , 2001. DMR.5294.

  180. Universal sensor interface (USI): preliminary specifications (version 1.0)
    X. Li; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 2001.

  181. A theoretical and experimental study of the piezojunction effect in silicon and its application in new sensor structures STW: Del.3908-4
    F. Fruett; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 2001.

  182. Non-destructive sterility and leakage testing of packaged food products by smart impendance measurements: voortgangs rapport 4
    S. Nihtianov; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 2001. DEL 66.4369.

  183. Universal sensor interface (USI): application note (version 1.0)
    X. Li; G.C.M. Meijer; M. van de Lee;
    Technische Universiteit Delft, Faculty ITS, , 2001.

  184. A theoretical and experimental study of the piezojunction effect in silicon and its application in new sensor structures STW: Del.3908-5
    F. Fruett; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 2001.

  185. A high-performance universal sensor interface
    X. Li; G.C.M. Meijer; R. de Boer;
    In SIocn'01: conference proceedings,
    IEEE, pp. 19-22, 2001.

  186. The scaling of multiple sensor signals with a wide dynamic voltage range
    Guijie Wang; G.C.M. Meijer;
    In {E Obermeier} (Ed.), Transducers '01: technical papers Vol 1,
    Springer, pp. 84-87, 2001.

  187. A multi-period interface system for impedance measurements
    B. Iliev; S. Nihtianov; G.P. Shterev; G.C.M. Meijer;
    In SIcon'01:conference proceedings,
    IEEE, pp. 276-280, 2001.

  188. Movement sensor for art application
    G. Chao; G.C.M. Meijer;
    In SAFE - ProRISC - SeSens 2001: proceedings. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 795-798, 2001.

  189. Fast measurement systems for determination the position on a resistive touch-screen
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In SAFE - ProRISC - SeSens 2001: proceedings. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 761-764, 2001.

  190. A Novell method of reading the time-domain sensor signals
    G. Chao; G.C.M. Meijer;
    In SAFE - ProRISC - SeSens 2001: proceeding. Semiconductor Advances for Future Electronics - Program for Research on Integrated Systems and Circuits - Semiconductor Sensor and Actuator Technology,
    STW Technology Foundation, pp. 371-373, 2001.

  191. An accurate measurement system for thermopiles
    P. Avramov; X. Li; G.C.M. Meijer; M. van de Lee;
    In {M Elwenspoek} (Ed.), Proceedings,
    Kluwer, pp. 167-172, 2001.

  192. The piezojunction effect as an alternative to the piezoresistive effect for low-power silicon mechanical-stress micro sensors
    F. Fruett; G.C.M. Meijer;
    In Proceedings,
    s.n., pp. 169-170, 2001.

  193. A low-cost and accurate conductance-measurement system
    X. Li; G.C.M. Meijer;
    In {M Elwenspoek} (Ed.), Proceedings,
    Kluwer, pp. 143-147, 2001.

  194. Low-cost system to determenate the X-Y position in a resistive touch-screen
    R.N. Aguilar Cardenas; G.C.M. Meijer;
    In {M Elwenspoek} (Ed.), Proceedings,
    Kluwer, pp. 65-69, 2001.

  195. Movement sensor for art application
    C. Guan; G.C.M. Meijer;
    In Electronics ET'2001: proceedings of the conference book 2,
    Technical University Sofia, pp. 81-86, 2001. niet eerder opgevoerd.

  196. A capactive-sensor interface circuit based on a first-order charge-balanced sc-oscillator
    X. Li; G.C.M. Meijer;
    In IMTC 2001: proceedings,
    IEEE, pp. 282-285, 2001.

  197. A measurement system for thermopiles with temperature compensation
    P.M. Avramov; G.C.M. Meijer; H.M.M. Kerkvliet;
    In Electronics ET'2001: The tenth international scientific and applied science conference,
    Technical University Sofia, pp. 116-120, 2001. niet eerder opgevoerd.

  198. Low-cost system for measuring plasma resistance
    B.P. Iliev; G.A.M. Pop; G.C.M. Meijer;
    In Electronics ET'2001: proceedings of the conference book 1,
    Technical University Sofia, pp. 44-48, 2001. niet eerder opgevoerd.

  199. The temperature characteristics of bipolar transistors fabricated in CMOS technology
    Guijie Wang; G.C.M. Meijer;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 87, pp. 81-89, 2000.

  200. Measurement and compensation of Piezoresistive coefficient Pi 44 for minority-carrier concentration
    F. Fruett; G.C.M. Meijer;
    Electronics Letters,
    Volume 36, Issue 2, pp. 173-175, 2000.

  201. The Piezojunction effect in NPN and PNP vertical transistors and its influence on silicon temperature sensors
    F. Fruett; Guijie Wang; G.C.M. Meijer;
    Sensors and Actuators A: Physical: an international journal devoted to research and development of physical and chemical transducers,
    Volume 85, Issue 1-3, pp. 70-74, 2000.

  202. Elimination of shunting conductance effects in a low-cost capacitive-sensor interface
    X. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 49, Issue 3, pp. 531-534, 2000.

  203. Elimination of shunting conductance effects in a low-cost capacitive-sensor interface
    X. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 49, Issue 3, pp. 531-534, 2000.

  204. The influence of electric-field bending on the nonlinearity of capacitive sensors
    X. Li; G. de Jong; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 49, Issue 2, pp. 256-259, 2000.

  205. A high-temperature electronic system for pressure-transducers
    P.C. de Jong; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 49, Issue 2, pp. 365-370, 2000.

  206. The influence of the Piezojunction effect at different temperatures on the accuracy of silicon temperature sensors
    F. Fruett; G.C.M. Meijer;
    s.n., , pp. 153-157, 2000.

  207. An accurate, low-cost resistive-sensor interface with a multiple-signal calibration technique
    X. Li; G.C.M. Meijer;
    {C Nemarich} (Ed.);
    IEEE, , pp. 281-284, 2000.

  208. Interface circuit for impedance measurement to test sterility of food products
    S. Nihtianov; G.P. Shterev; N. Petrov; G.C.M. Meijer;
    {C Nemarich} (Ed.);
    IEEE, , pp. 687-691, 2000.

  209. A novel technique to measure two independent components of impedance sensors with a simple relaxation oscillator
    S. Nihtianov; G.P. Shterev; B. Iliev; G.C.M. Meijer;
    {C Nemarich} (Ed.);
    IEEE, , pp. 674-678, 2000.

  210. A novel switched-capacitor front end for capacitive sensors with wide dynamic range
    G.C.M. Meijer; V.P. Jordanov;
    In The eight national scientific and applied conference ELECTRONICS '99: proceedings book 1,
    Technical University Sofia, pp. 24-29, 2000.

  211. A new concept for impedance sensor interfacing with first order oscillator
    S. Nihtianov; G.C.M. Meijer;
    In The eight national scientific and applied conference ELECTRONICS '99: proceedings book 1,
    Technical University Sofia, pp. 62-67, 2000.

  212. A mechanical stress factor using the Piezojunction effect
    F. Fruett; G.C.M. Meijer;
    In {JP Veen} (Ed.), SAFE-ProRisc-SeSens 2000: proceedings,
    STW Technology Foundation, pp. 633-638, 2000.

  213. A low-cost, high-performance universal sensor interface
    X. Li; G.C.M. Meijer; P. Avramov; M. van de Lee;
    In {JP Veen} (Ed.), SAFE-ProRISC-SeSens 2000: proceedings,
    STW Technology Foundation, pp. 659-663, 2000.

  214. A new concept for impedance sensor interfacing with first order oscillator
    S. Nihtianov; G.C.M. Meijer;
    In Proceedings, book 1,
    Technical University Sofia, pp. 62-67, 2000.

  215. An accurate switched-capacitor amplifier with a rail-to-rail CM input range
    Guijie Wang; G.C.M. Meijer;
    In {JP Veen} (Ed.), SAFE-ProRISC-SeSens 2000: proceedings,
    STW Technology Foundation, pp. 703-707, 2000.

  216. A novel switched-capacitor front end for capacitive sensors with wide dynamic range
    G.C.M. Meijer; V.P. Jordanov;
    In Proceedings, book 1,
    Technical University Sofia, pp. 24-29, 2000.

  217. Features and limitations of CMOS voltage references
    G.C.M. Meijer; Guijie Wang;
    In Proceedings, book 1,
    Technical University Sofia, pp. 17-23, 2000.

  218. Accurate DEM SC amplification of small differential voltage signal with CM level from ground to Vdd
    Guijie Wang; G.C.M. Meijer;
    In {VK Varadan} (Ed.), Proceedings of SPIE, vol. 3990,
    International Society for Optical Engineering, pp. 36-42, 2000.

  219. A low-cost, high-performance universal sensor interface
    X. Li; G.C.M. Meijer; P. Avramov; M. van de Lee;
    In Proceedings,
    STW Technology Foundation, pp. 659-663, 2000.

  220. Exploration of the Piezojunction effect using PNP lateral transistors on [100] silicon
    F. Fruett; G.C.M. Meijer;
    In {R Reus}, de; {S Bouwstra} (Ed.), Eurosensors XIV,
    Mikroelektronik Centret, pp. 519-522, 2000.

  221. A system for testing the sterility of food products with impedance measurement
    G.P. Shterev; S. Nihtianov; N. Petrov; G.C.M. Meijer;
    In ET'2000: proceedings book 1,
    s.n., pp. 79-86, 2000.

  222. Universal sensor interface
    X. Li; G.C.M. Meijer; P. Avramov; M. van de Lee;
    In ET'2000: proceedings book 1,
    s.n., pp. 41-46, 2000.

  223. Interface system for impedance measurement based on a relaxation oscilator
    B. Iliev; S. Nihtianov; G.P. Shterev; G.C.M. Meijer;
    In ET'2000: proceedings book 1,
    s.n., pp. 71-78, 2000.

  224. Stress sensors based on the use of the piezojunction effect
    F. Fruett; G.C.M. Meijer;
    In ET'2000: proceedings book 1,
    s.n., pp. 47-52, 2000.

  225. Features and limitations of CMOS voltage references
    G.C.M. Meijer; Guijie Wang;
    In The eight national scientific and applied conference ELECTRONICS '99: proceedings book 1,
    Technical University Sofia, pp. 17-23, 2000.

  226. Low-cost multiple sensor systems
    G.C.M. Meijer;
    Journal {"}A{"},
    Volume 40, Issue 1, pp. 20-25, 1999.

  227. Integrated interfaces for low-cost multiple-sensor systems
    G.C.M. Meijer; F.M.L. van der Goes; P.C. de Jong; X. Li; F.N.Toth;
    Journal of Intelligent Material Systems and Structures,
    Volume 10, pp. 105-115, 1999.

  228. Compensation of piezoresistivity effect in p-type implanted resistors
    F. Fruett; G.C.M. Meijer;
    Electronics Letters,
    Volume 35, Issue 18, pp. 1587-1588, 1999.

  229. A theoretical and experimental study of the piezojunction effect in silicon and its application in new sensor structures STW: Del.3908-3
    F. Fruett; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 1999.

  230. A theoretical and experimental study of the piezojunction effect in silicon and its application in new sensor structures STW: Del.3908-2
    F. Fruett; G.C.M. Meijer;
    Technische Universiteit Delft, Faculty ITS, , 1999.

  231. A smart accurate presure-transducer for high-temperature applications
    P.C. de Jong; G.C.M. Meijer;
    {V Piuri}; {M Savino} (Ed.);
    IEEE, , pp. 309-314, 1999.

  232. A low-cost and reliable interface for capacitive sensors
    X. Li; G.C.M. Meijer;
    {V Piuri}; {M Savino} (Ed.);
    IEEE, , pp. 1256-1259, 1999.

  233. The effect of electric-field bending on the linearity of capacitive position sensors with various elecrode structures
    X. Li; G. de Jong; G.C.M. Meijer;
    {V Piuri}; {M Savino} (Ed.);
    IEEE, , pp. 1348-1351, 1999.

  234. An experimental study of the influence of the piezojunction effect on the accuracy of silicon temperature sensors
    F. Fruett; G.C.M. Meijer;
    In {JP Veen} (Ed.), SAFE99: proceedings. ProRISC99: proceedings [CD-ROM],
    STW Technology Foundation, pp. 143-146, 1999.

  235. An experimental study of the influence of the piezojunction effect on the accuracy of silicon temperature sensors
    F. Fruett; G.C.M. Meijer;
    In ICMP 99 technical digest,
    s.n., pp. 75-80, 1999.

  236. Dynamic voltage references in CMOS technology
    G.C.M. Meijer; Guijie Wang;
    In ICMP 99 technical digest,
    s.n., pp. 1-8, 1999.

  237. A test structure to characterize the piezojunction effect and its influence on silicon temperature sensors
    F. Fruett; G.C.M. Meijer;
    In {M. Bartek} (Ed.), Eurosensors XIII: proceedings [CD-ROM],
    Delft University of Technology, pp. 53-56, 1999.

  238. The temperature characteristics of bipolar transistors for CMOS temperature sensors
    Guijie Wang; G.C.M. Meijer;
    In Eurosensors XIII,
    s.n., pp. 553-556, 1999.

  239. Non-destructive on-line sterility testing of long-shelf-life aseptically packaged food products by impedance mearurements
    S. Nihtianov; G.C.M. Meijer;
    In 1999 IEEE Autotestcon proceedings,
    IEEE, pp. 243-249, 1999.

  240. A novel low-cost noncontact resistive potentiometric sensor for the measurement of low speeds [niet eerder opgevoerd]
    X. Li; G.C.M. Meijer;
    IEEE Transactions on Instrumentation and Measurement,
    Volume 47, Issue 3, pp. 776-781, 1998.

  241. A low-cost and accurate interface for voltage-generating sensors [niet eerder opgevoerd]
    X. Li; G.C.M. Meijer;
    In Proceedings of the conference. Book 1,
    Technical University Sofia, pp. 82-86, 1998.

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Last updated: 22 Aug 2023