Cristiano Calligaro scite author profile

Abstract-An architectural performance comparison of bandgap voltage reference variants, designed in a 0.18 µm CMOS process, is performed with respect to single event transients. These are commonly induced in microelectronics in the space radiation environment. Heavy ion tests (Silicon, Krypton, Xenon) are used to explore the analog single-event transients and have revealed pulse quenching mechanisms in analogue circuits. The different topologies are compared, in terms of cross-section, pulse duration and pulse amplitude. The measured results, and the explanations behind the findings, reveal important guidelines for designing analog integrated circuits, which are intended for space applications. The paper includes an analysis on how pulse quenching occurs within the indispensable current mirror, which is used in every analog circuit.

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Design of a rad-hard library of digital cells for space applications

Stabile

Liberali

Calligaro

2008

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Abstract-This paper proposes a design methodology for a digital library of cells resistant to cosmic radiation. Most important effects due to radiation are avoided or mitigated using ad hoc design techniques. Fault injection techniques are used to validate the design. Simulations results demonstrate that the cells designed in a 180 nm CMOS technology are tolerant to 1.5 mA current peak due to interaction with a single high-energy particle.

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Technological and design constraints for multilevel flash memories

Calligaro

Manstretta²,

Modelli³

et al.

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Positive and negative CMOS voltage multiplier for 5-V-only flash memories

Calligaro

Gastaldi²,

Malcovati³

et al.

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Layout-oriented simulation of non-destructive single event effects in CMOS IC blocks

Liberali

Stabile

et al. 2009

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Radiation hardened 2Mbit SRAM in 180nm CMOS technology

Arbat

Calligaro

Roizin

et al. 2012

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Low-Power, Subthreshold Reference Circuits for the Space Environment: Evaluated with γ-rays, X-rays, Protons and Heavy Ions

et al. 2019

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The radiation tolerance of subthreshold reference circuits for space microelectronics is presented. The assessment is supported by measured results of total ionization dose and single event transient radiation-induced effects under γ -rays, X-rays, protons and heavy ions (silicon, krypton and xenon). A high total irradiation dose with different radiation sources was used to evaluate the proposed topologies for a wide range of applications operating in harsh environments similar to the space environment. The proposed custom designed integrated circuits (IC) circuits utilize only CMOS transistors, operating in the subthreshold regime, and poly-silicon resistors without using any external components such as compensation capacitors. The circuits are radiation hardened by design (RHBD) and they were fabricated using TowerJazz Semiconductor’s 0.18 μm standard CMOS technology. The proposed voltage references are shown to be suitable for high-precision and low-power space applications. It is demonstrated that radiation hardened microelectronics operating in subthreshold regime are promising candidates for significantly reducing the size and cost of space missions due to reduced energy requirements.

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Radiation-hardened techniques for CMOS flash ADC

Gatti¹,

Calligaro²,

Pikhay

et al. 2014

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