Design and Characterization of 10 Gb/s and 1 Grad TID-Tolerant Optical Modulator Driver

Ciarpi, Gabriele; Cammarata, Simone; Monda, Danilo; Faralli, S.; Velha, Philippe; Magazzù, G.; Palla, F.; Saponara, Sergio

doi:10.1109/tcsi.2022.3171827

Cited by 7 publications

(2 citation statements)

References 45 publications

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“…effects and efficacy of the implemented countermeasures, fully-integrated SiPh-based transceivers (TRXs) prototypes are already under development to provide next-generation readout systems for high-energy physics (HEP) detectors [16][17][18][19][20]. In comparison to existing optoelectronic modules, SiPh also presents a distinct advantage in terms of transmission capabilities.…”

Section: Jinst 19 C03009mentioning

confidence: 99%

Compact silicon photonic Mach-Zehnder modulators for high-energy physics

Cammarata,

Palla,

Saponara

et al. 2024

J. Inst.

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The characterization of compact non-traveling-wave Mach-Zehnder modulators for optical readout in high-energy physics experiments is reported to provide power-efficient alternatives to conventional traveling-wave devices and a more resilient operation compared to ring modulators. Electro-optical small-signal and large-signal measurements showcase the performances of custom NTW-MZMs designed and fabricated in iSiPP50G IMEC's technology in the framework of INFN's FALAPHEL project. Bit-error-rate results demonstrate their potential suitability for optical links up to 25 Gb/s when equipped with either conventional deep-etched or radiation-hardened shallow-etched free-carrier-based phase shifters.

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Section: Jinst 19 C03009mentioning

confidence: 99%

Compact silicon photonic Mach-Zehnder modulators for high-energy physics

Cammarata,

Palla,

Saponara

et al. 2024

J. Inst.

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“…Non-exhaustive examples of applications in which high temperatures undermine electronics' reliability are space, avionics, and aerospace applications, where the temperature can reach values up to 150 • C [1][2][3][4], as well as automotive and several industrial sectors, where the maximum temperature may reach 200 • C [5,6]. On the other hand, in space and aerospace environments, radiation can severely undermine electronics' reliability [7][8][9]. Therefore, the characterization of electronic components designed to operate in harsh environments needs to be performed in very high-temperature conditions, and in the presence of radiation.…”

Section: Introductionmentioning

confidence: 99%

An Integrated Charge Pump for Phase-Locked Loop Applications in Harsh Environments

Mestice,

Ciarpi,

Rossi

et al. 2024

Electronics

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Among all the functions that electronics currently perform, clock synthesis has a backbone role. Charge pump phase-locked loops (CP-PLL) are widely used to accomplish clock synthesis thanks to their versatility. One of the most critical parts of CP-PLLs is the charge pump, which greatly influences the system’s performance. Even though several high-performance charge pumps have been proposed in the past, with the quick spread of electronics in all the engineering fields, the design of such electronic devices has encountered several additional challenges dictated by external environmental conditions. Examples of these engineering sectors are space, aerospace, industrial, and automotive applications, where the charge pump has to face high environmental temperatures and radiation effects. As a consequence, its design and experimental characterization have to be performed to ensure reliability when operating in harsh conditions. However, to the best of the authors’ knowledge, no works in the literature have ever presented a complete charge pump design and characterization in such harsh environments. Therefore, to fill this gap, this paper presents a charge pump for PLL applications specifically designed to reach operating temperatures up to 200 °C and total ionizing dose levels up to 100 Mrad. All design choices have been experimentally verified and are discussed throughout the paper in detail. With the proposed design, we obtained an output current variation of less than 8% at 200 °C and less than 2.5% at 100 Mrad. As opposed to the CPs that can be found in the literature, these results were measured on silicon. The performed measurements confirm that the current variation at 200 °C is better than that of the state-of-the-art CPs operating at lower temperatures, which, moreover, were only simulated.

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