Showing posts with label optoelectronics. Show all posts
Showing posts with label optoelectronics. Show all posts

Sep 27, 2022

IRPhE’2022 Yerevan Armenia

International Conference on Microwave & THz Technologies and Optoelectronics
IRPhE’2022
Dedicated to 100-years jubilee of academician Emil Mirzabekyan
September 27-29, 2022
Sponsors

Venue: National Academy of Sciences, Marshall Baghramian Ave. 24, Yerevan, Armenia
Organized by: Institute of Radiophysics and Electronics, Armenian National Academy of Sciences, Committee of Science of Armenia

IRPhE’2022 Main Topics:
  • Microwave devices, antennas, propagations and remote sensing
  • THz technique, spectroscopy and applications
  • Alternative semiconductor and dielectric materials, electronic devices
  • Optoelectronics, photonics
Conference Chairs:
  • Arsen Hakhoumian, (Dr. Sc., Corr. Member NAS RA, IRPhE, Armenia)
  • Tigran Zakaryan (Dr. CEO, IRPhE, Armenia)
Program Committee:
  • Radik Martirosyan, (IRPhE, Armenia)
  • Arsen Hakhoumian, (IRPhE, Armenia, Chair)
  • Kiejin Lee (SogangUniversity, South Korea)
  • Sadayuki Yoshitomi (GigaChips, Japan)
  • Kodo Kawase (Nagoya University, Japan)
  • Robert Minasian (Sydney University, Australia)
  • Mher Ghulinyan (Fondazione Bruno Kessler, Italy)
  • Stepan Petrosyan (IRPhE, Armenia)
  • Yuri Avetisyan (YSU, Armenia)
  • Khachik Nerkararyan (YSU, Armenia)
Organizing Committee:
  • Tigran Zakaryan, (IRPhE, Chair)
  • Arsen Hakhoumian, (IRPhE, Co-chair)
  • Ashkhen Yesayan, (IRPhE, RA)
  • Emil Asmaryan (IRPhE, RA)
  • Hayk Manukyan (VIAVI Solutions, UK)
  • Anahit Mnatsakanyan (IRPhE, RA)
PROGRAM
is available online

Feb 11, 2021

[thesis] SPICE modeling of light and radiation effects in ICs

A novel approach for SPICE modeling of light and radiation effects in ICs
Chiara ROSSI
Présentée le 29 janvier 2021
à la Faculté des sciences et techniques de l’ingénieur Groupe de scientifiques IEL
Programme doctoral en microsystèmes et microélectronique
pour l’obtention du grade de Docteur ès Sciences
DOI:10.5075/epfl-thesis-8422

Modeling the interaction of ionizing radiation, either light or ions, in integrated circuits is essential for the development and optimization of optoelectronic devices and of radiation-tolerant circuits. Whereas for optical sensors photogenerated carriers play an essential role, high energy ionizing particles can be a severe issue for circuits, as they create high density of excess carriers in ICs substrate, causing parasitic signals. In particular, recent advances in CMOS scaling have made circuits more sensitive to errors and dysfunctions caused by radiation-induced currents, even at the ground level. TCAD simulations of excess carriers generated by light or radiation are not dedicated to large scale circuit simulations since only few devices can be simulated at a time and computation times are too long. Conversely, SPICE simulations are faster, but their accuracy is strictly dependent on the correctness of the compact models used to describe the devices, especially when dealing with photocurrents and parasitic radiation-induced currents.
The objective of this thesis is to develop a novel modeling approach for SPICE compatible simulations of electron-hole pairs generated by light and by high energy particles. The approach proposed in this work is based on the Generalized Lumped Devices, previously developed to simulate parasitic signals in High Voltage MOSFET ICs. Here, the model is extended to include excess carriers generation. The developed approach allows physics-based simulations of semiconductor structures, hit by light or radiation, that can be run in standard circuit simulators without the need for any empirical parameter, only relying on the technological and geometrical parameters of the structure, and without any predefined compact model. The model is based on a coarse mesh of the device to obtain an equivalent network of Generalized Lumped Devices. The latter predicts generation of excess carriers and their propagation, recombination and collection at circuit nodes through the definition of equivalent voltages, proportional to the excess carrier concentrations, and equivalent currents, proportional to the excess carrier gradients. The model is validated with commercial TCAD numerical simulations for different scenarios. Regarding light effects, the proposed strategy is applied to simulate various optoelectronic devices. Complete DC I-V characteristics of a solar cell and transient response of a photodiode are studied. Next, phototransistors are considered. After, a full pixel of a 3T-APS CMOS image sensor is analyzed. The photosensing device, described with Generalized Devices, is co-simulated with the in-pixel circuit, described with compact models. The impact of semiconductor parameters on pixel output and on crosstalk between adjacent pixels is predicted. Finally, radiation-induced soft errors in ICs are examined. Alpha particles at different energies hitting the substrate are simulated. Parasitic currents collected at contacts are studied as a function of particles position and energy. Funneling effect, which is a phenomenon specific to high injection, is also included in the model.
This work shows that the Generalized Lumped Devices approach can be successfully used for SPICE simulations of optoelectronic devices and for prediction of radiationinduced parasitic currents in ICs substrate. This thesis is a first step towards a complete and flexible tool for excess carriers modeling in standard circuit simulators.
Fig: Layout, mesh (gray dashed lines) and equivalent network of Generalized Lumped Devices (Generalized Homojunctions, Resistors and Diodes). The structure is uniformly illuminated from the left side, justifying a 1D discretization scheme.