Mohamed Lamine Hafiane scite author profile

Mohamed Lamine Hafiane

5Publications

94Citation Statements Received

23Citation Statements Given

How they've been cited

144

How they cite others

Affiliations

University of Bonn, University of Batna 1, Technische Universität Berlin

Publications

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An Enhanced Technique for Ultrasonic Flow Metering Featuring Very Low Jitter and Offset

Hamouda

Manck

Hafiane

et al. 2016

Sensors

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This paper proposes a new, improved method for water flow metering. It applies to a transit time ultrasonic flow meter device. In principle, the flow of a given liquid in a pipe is obtained by measuring the transit times of an ultrasonic wave in the upstream and downstream directions. The difference between these times is, in theory, linearly proportional to the liquid flow velocity. However, the fainter the flow is, the smaller the transit time difference (TTD) is. This difference can be as low as a few picoseconds, which gives rise to many technical difficulties in measuring such a small time difference with a given accuracy. The proposed method relies on measuring the TTD indirectly by computing the phase difference between the steady-state parts of the received signals in the upstream and downstream directions and by using a least-square-sine-fitting technique. This reduces the effect of the jitter noise and the offset, which limit measurement precision at very low flow velocity. The obtained measurement results illustrate the robustness of the proposed method, as we measure the TTD at no-flow conditions, with a precision as low as 10 ps peak-to-peak and a TTD offset of zero, within a temperature range from room temperature to 80˝C. This allows us to reach a smaller minimum detectable flow when compared with previous techniques. The proposed method exhibits a better trade-off between measurement accuracy and system complexity. It can be completely integrated in an ASIC (application specific integrated circuit) or incorporated in a CPU-or micro-controller-based system.

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An approach based on neural computation to simulate the nanoscale CMOS circuits: Application to the simulation of CMOS inverter

Djeffal

Chahdi

Benhaya

et al. 2007

Solid-State Electronics

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Design and simulation of a nanoelectronic DG MOSFET current source using artificial neural networks

Djeffal

Dibi

Hafiane

et al. 2007

Materials Science and Engineering: C

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Depth Resolution Enhancement Technique for CMOS Time-of-Flight 3-D Image Sensors

Hafiane

Wagner²,

Dibi

et al. 2012

IEEE Sensors J.

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On the Capability of Artificial Neural Networks to Compensate Nonlinearities in Wavelength Sensing

Hafiane

Dibi

Manck

2009

Sensors

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An intelligent sensor for light wavelength readout, suitable for visible range optical applications, has been developed. Using buried triple photo-junction as basic pixel sensing element in combination with artificial neural network (ANN), the wavelength readout with a full-scale error of less than 1.5% over the range of 400 to 780 nm can be achieved. Through this work, the applicability of the ANN approach in optical sensing is investigated and compared with conventional methods, and a good compromise between accuracy and the possibility for on-chip implementation was thus found. Indeed, this technique can serve different purposes and may replace conventional methods.

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