Your search keyword '"Anurag Behera"' showing total 7 results

1. Breaking the rules of time-domain diffuse optics: working with 1 cm2 SiPM and well-beyond the single-photon statistics

Author

Laura Di Sieno, Elisabetta Avanzi, Fabio Acerbi, Alberto Gola, Michele Lacerenza, Anurag Behera, Davide Contini, and Alberto Dalla Mora

Subjects

time-domain diffuse optics, single-photon detector, time-domain diffuse optics, turbid media, single-photon statistics, single-photon detector, turbid media, single-photon statistics

Published

2022

2. Time-domain diffuse optics beyond pile-up limits: a simulation study based on relevant figures of merit

Author

Elisabetta Avanzi, Laura Di Sieno, Anurag Behera, Davide Contini, and Alberto Dalla Mora

Subjects

pile-up distortion, Diffuse optical imaging, Single photon statistics

Abstract

Large-area detectors for time-domain diffuse optics are increasingly available, with enormous gain in collected light intensity. Pile-up distortion is nowadays the main limit, here studied to anticipate the possibility of a new working modality.

Published

2021

3. Silicon photomultiplier-based detection module with up to 1 cm2 area to push time-domain diffuse optics performances

Author

Laura Di Sieno, Alberto Dalla Mora, Anurag Behera, Alberto Gola, and Fabio Acerbi

Subjects

optical properties, diffuse optical imaging, sensors, optical properties, diffuse optical imaging, single photon detector, time domain diffuse optical spectroscopy, single photon detector, sensors, time domain diffuse optical spectroscopy

Published

2021

4. Time-Resolved multi-wavelength, dual-channel system for diffuse optical spectroscopy: performance assessment

Author

Alberto Tosi, Mauro Buttafava, Anurag Behera, Alberto Dalla Mora, Laura Di Sieno, Marta Zanoletti, Marco Renna, Davide Contini, and Pranav Lanka

Subjects

sezele, Computer science, Scattering, Linearity, Multi wavelength, 01 natural sciences, Imaging phantom, 010309 optics, Homogeneous, Attenuation coefficient, 0103 physical sciences, Electronic engineering, Time-resolved spectroscopy, 010306 general physics, Spectroscopy, SPAD, Time-Domain Diffuse Optics, Time-Resolved Spectroscopy

Abstract

In this paper we present the ex-vivo characterization of a full-custom made multi-wavelength, two channel Time-Resolved Spectroscopy (TRS) module developed with the aim of being integrated in to a multi-modal spectroscopic device. This module overcomes all the main drawbacks of systems based on time-domain techniques such as high complexity and bulkiness while guaranteeing performances comparable to expensive state-of-the-art available devices. Each sub-component of the module has been tailored and optimized to meet all the above-mentioned requirements. In order to assess and translate the performances of these tools for effective clinical use, we characterized the system following the guidelines of common standardization protocols. By following MEDPHOT guidelines, the linearity and accuracy in retrieving absolute values of absorption and scattering coefficients were determined by means of measurements on homogeneous phantoms. Finally, by means of a mechanically switchable solid inhomogeneous phantom (developed under the nEUROPT project) we simulated the clinical problem of detecting and localizing an absorption perturbation in a homogeneous background with broad applications such as detection of cancer lesions, thyroid, etc.

Published

2019

5. Multi-wavelength dual-detection channel system for time-resolved near-infrared spectroscopy

Author

Marta Zanoletti, Anurag Behera, Alberto Dalla Mora, Alberto Tosi, Marco Renna, Mauro Buttafava, Davide Contini, and Laura Di Sieno

Subjects

Materials science, near-infrared spectroscopy, Optical power, time-to-digital converter, 02 engineering and technology, time-resolved, 01 natural sciences, Imaging phantom, law.invention, 010309 optics, Time-to-digital converter, 020210 optoelectronics & photonics, Silicon photomultiplier, Optics, law, pulsed laser, 0103 physical sciences, Diffuse optics, single-photon detector, time-correlated single-photon counting, 0202 electrical engineering, electronic engineering, information engineering, Diode, sezele, business.industry, Near-infrared spectroscopy, Laser, Picosecond, business

Abstract

We present a new full-custom instrument for time-domain diffuse optical spectroscopy developed within Horizon 2020 LUCA (Laser and Ultrasound Co-Analyzer for thyroid nodules) project. It features eight different picosecond diode lasers (in the 635 - 1050 nm range), two 1.3 × 1.3 mm2 active-area SiPMs (Silicon PhotoMultipliers) working in single-photon mode and two 10 ps resolution time-to-digital converters. A custom FPGA-based control board manages the instrument and communicates with an external computer via USB connection. The instrument proved state-of-the-art performance: an instrument response function narrower than 160 ps (fullwidth at half-maximum), a long-term measurement stability better than 1%, and an output average optical power higher than 1 mW at 40 MHz. The instrument has been validated with phantom measurements.

Published

2019

6. Large area SiPM and high throughput timing electronics: toward new generation time-domain instruments

Author

Alessandro Torricelli, Benedikt Krämer, Felix Koberling, Davide Contini, Alberto Dalla Mora, Antonio Pifferi, Sumeet Rohilla, Anurag Behera, and Laura Di Sieno

Subjects

Photomultiplier, Photon, Computer science, 010401 analytical chemistry, Detector, Time-Domain Diffuse Optics, Linearity, Large area SiPM, 01 natural sciences, 0104 chemical sciences, Numerical aperture, Time-Domain Diffuse Optics, Large area SiPM, High throughput systems, 010309 optics, Silicon photomultiplier, Robustness (computer science), 0103 physical sciences, High throughput systems, Electronic engineering, Electronics

Abstract

We present here a novel time-domain diffuse optical detection chain consisting of a large area Silicon PhotoMultipliers (SiPM) coupled to a high count-rate timing electronics (TimeHarp 260 PICO) to achieve sustainable count-rates up to 10 Mcps without significant distortions to the distribution of time-of-flight (DTOF). Thanks to the large area of the detector (9 mm2) and the possibility to directly place it in contact with the sample (thus achieving a numerical aperture close to unity), the photon collection efficiency of the proposed detection chain is almost two orders of magnitude higher than traditional fiber-mounted PMT-based systems. This allows the detection also of the few late photons coming from deeper layers at short acquisition times, thus improving the robustness of the detection of localized inhomogeneities. We then demonstrate that, despite the high dark count rate of the detector, it is possible to reliably extract the optical properties of calibrated phantoms, with proper linearity and accuracy. We also explore the capability of the new detection chain for detecting brain activations. This work opens up the possibility of ultimate performance in terms of high signal and photon throughput, with compact, low cost, relatively simple front-end electronics detector coupled to innovative timing electronics, with exciting opportunities to expand it to tomographic applications.

Published

2019

7. Study of optimal measurement conditions for time-domain diffuse optics systems

Author

Alberto Dalla Mora, Fabrizio Martelli, Anurag Behera, Antonio Pifferi, and Laura Di Sieno

Subjects

Physics, business.industry, Scattering, medical imaging, diffusive media, time-domain optical imaging, Heavy traffic approximation, 01 natural sciences, 010309 optics, Optics, single-photon detector, simulations, 0103 physical sciences, Radiative transfer, Figure of merit, Sensitivity (control systems), Time domain, Born approximation, 010306 general physics, Absorption (electromagnetic radiation), business

Abstract

Light is a powerful non-invasive tool that can be exploited to probe highly scattering media like biological tissues for different purposes, from the detection of brain activity to the characterization of cancer lesions. In the last decade, timedomain diffuse optics (TDDO) systems demonstrated improved sensitivity when using time-gated acquisition chains and short source-detector separations (ρ), both theoretically and experimentally. However, the sensitivity to localized absorption changes buried inside a diffusive medium strongly depends on many parameters such as: SDS, laser power, delay and width of the gating window, absorption and scattering properties of the medium, instrument response function (IRF) shape, etc. In particular, relevant effects due to slow tails in the IRF were noticed, with detrimental effects on performances. We present simulated experimental results based on the diffusion approximation of the Radiative Transfer Equation and the perturbation theory subjected to the Born approximation. To quantify the system sensitivity to deep (few cm) and localized absorption perturbations, we exploited contrast and contrast-to-noise ratio (CNR), which are internationally agreed on standardized figures of merit. The purpose of this study is to determine which parameters have the greatest impact on these figures of merit, thus also providing a range of best operative conditions. The study is composed by two main stages: the former is a comparison between simulations and measurements on tissue-mimicking phantom, while the latter is a broad simulation study in which all relevant parameters are tuned to determine optimal measurement conditions. This study essentially demonstrates that under the influence of the slow tails in the IRF, the use of a small SDS no longer corresponds to optimal contrast and CNR. This work sets the ground for future studies with next-generation of TDDO components, presently under development, providing useful hints on relevant features to which one should take care when designing TDDO components.