Departamento

Departamento de Ingeniería Eléctrica

Cursos que dicta

Pregrado

  • Fund. de Sistemas de Comunicaciones
  • Procesamiento de Señales e Imágenes
  • Diseño e Implementación de Dispositivos Lógicos Programables

Producción Científica

Proyectos

  • Fondecyt 11201348, Fpga-based embedded systems for information processing in an ultrafast and highdimensional spatial division multiplexing quantum technology, Investigador Responsable, 2020.
  • PAI77190088, fortalecimiento de la docencia e investigación en el área de señales y telecomunicaciones, con énfasis en electrónica embebida y comunicaciones ópticas, de la Facultad de Ingeniería UCSC, Investigador Responsable, 2019.
  • Fondecyt 3170596, criptografía cuántica experimental entre múltiples usuarios a través de una red de fibra óptica sin repetidores, Investigador Responsable 2017.
  • Fondecyt 1150101, device-independent quantum communications compatible with optical fiber networks, personal técnico, 2015.
  • Fondecyt 1110937, study and design of diffractive polarized programmable optical elements. Application of real time controlled polarized beams shapes for optical trapping., personal técnico, 2011.
  • Fondecyt 1080383 quantum-key distribution based on non-orthogonal quantum states, personal técnico, 2008.
  • Fondecyt 11060477, physical implementations of multiphoton sources and distant entanglement protocols for quantum information processing, Personal técnico, 2006.

Publicaciones

  • J. Cariñe, S.A. Gómez, G.F. Obregón, E.S. Gómez, M. Figueroa, G. Lima, Post-measurement adjustment of the coincidence window in quantum optics experiments. IEEE Access 9, 94010-94016, 2021.
  • M.M. Taddei, J. Cariñe, D. Martínez, et al., Computational advantage from the quantum superposition of multiple temporal orders of photonic gates, PRX Quantum 2 (1),
    010320, 2021.
  • M. Farkas, N. Guerrero, J. Cariñe, G. Cañas, G .Lima, Selftesting mutually unbiased bases in higher dimensions with space-division multiplexing optical fiber technology, Physical Review Applied 15 (1), 014028, 2021.
  • A. Alarcon, P. González, J. Cariñe, G. Lima, G.B. Xavier, Polarization-independent single-photon switch based on a fiber-optical Sagnac interferometer for quantum communication networks, Optics Express 28 (22), 33731-33738, 2020.
  • M. Farkas, N. Guerrero, J. Cariñe, G. Cañas, G. Lima, Robust self-test of high-dimension mutually unbiased bases with commercial multi-core fiber, proceedings paper, 2020 IEEE Photonics Society Summer Topicals Meeting Series (SUM), 1-2, 2020.
  • J. Cariñe, G. Cañas, P. Skrzypczyk, et al., Multi-core fiber integrated multi-port beam splitters for quantum information processing, Optica 7 (5), 542-550, 2020
  • Edgar A. Aguilar, Máté Farkas, Daniel Martínez, Matías Alvarado, Jaime Cariñe, et al. Certifying an irreducible 1024-dimensional photonic state using refined dimension witnesses. Phys. Rev. Lett. (120) 230503-(1-6), 2018.
  • C. Abellán, … J. Cariñe, et al. Challenging local realism with human choices., Nature., vol. 557, p. 212, 2018.
  • G. Cañas, N. Vera, J. Cariñe, et al., High-dimensional decoy-state quantum key distribution over multicore telecommunication fibers., Phys. Rev. A., vol. 96, p. 022317, 2017.
  • Gustavo Cañas, Evelyn Acuña, Jaime Cariñe, et al. Experimental demonstration of the connection between quantum contextuality and graph theory. Phys. Rev. A. (94) 012337-(1-6), 2016.
  • J. Cariñe, R. Guzmán, F.A.Torres-Ruiz., Algorithm for dynamic Speckle pattern processing, Opt Lasers Eng., vol. 82, p. 56, 2016.
  • G. Carvacho, J. Cariñe, et al., Postselection-Loophole-Free Bell Test Over an Installed Optical Fiber Network., Phys. Rev. Lett, vol. 115, p. 030503, 2015.
  • A. Cuevas, G. Carvacho, G. Saavedra, J. Cariñe, et al., Long-distance distribution of genuine energy-time entanglement, Nature Comm., vol. 4, p. 2871, 2013

Líneas de investigación

  • Experimental quantum information
  • Optical communications
  • Real-time information processing in FPGA devices
  • Información cuántica experimental
  • Comunicaciones ópticas
  • Procesamiento de información en tiempo real con dispositivos FPGA