Quantum Face Recognition Protocol with Ghost Imaging

Salari, Vahid; Paneru, Dilip; Sağlamyürek, Erhan; Ghadimi, Milad; Abdar, Moloud; Rezaee, Reza; Aslani, M M; Barzanjeh, Shabir; Karimi, Ebrahim

doi:10.48550/arxiv.2110.10088

Cited by 2 publications

(2 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The envisaged BCI chip can be implanted on the interior surface of the skull to monitor in real-time UPE signals emanating from the cortex surface. The proposed chip is not only useful for BCI technology but also it can be used as a photonic sensor for imaging, spectroscopy and sensitive measurements at low light-levels in several applications from biological UPE to quantum optical processing [89]. Although our proposed technology is, admittedly, at the level of conjecture, requiring comprehensive tests and investigations for verification, we still envision complementary features as well as certain advantages over established technologies, including ECoG.…”

Section: Discussionmentioning

confidence: 99%

Are Brain-Computer Interfaces Feasible with Integrated Photonic Chips?

Salari¹,

Rodrigues²,

Sağlamyürek³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

The present paper examines the viability of a radically novel idea for brain-computer interface (BCI), which could lead to novel technological, experimental and clinical applications. BCIs are computer-based systems that enable either one-way or two-way communication between a living brain and an external machine. BCIs read-out brain signals and transduce them into task commands, which are performed by a machine. In closedloop, the machine can stimulate the brain with appropriate signals. In recent years, it has been shown that there is some ultraweak light emission from neurons within or close to the visible and near-infrared parts of the optical spectrum. Such ultraweak photon emission (UPE) reflects the cellular (and body) oxidative status, and compelling pieces of evidence are beginning to emerge that UPE may well play an informational role in neuronal functions. In fact, several experiments point to a direct correlation between UPE intensity and neural activity, oxidative reactions, EEG activity, cerebral blood flow, cerebral energy metabolism, and release of glutamate. Here, we propose a novel skull implant BCI that uses UPE. We suggest that a photonic integrated chip installed on the interior surface of the skull may enable a new form of extraction of the relevant features from the UPE signals. In the current technology landscape, photonic technologies advance rapidly and poised to overtake many electrical technologies, due to their unique advantages, such as miniaturization, high speed, low thermal effects, and large integration capacity that allow for high yield, volume manufacturing, and lower cost. For our proposed BCI, we make some major conjectures, which need to be experimentally verified, and hence we discuss the controversial parts, feasibility of technology and limitations, and potential impact of this envisaged technology if successfully implemented in the future.

show abstract

Section: Discussionmentioning

confidence: 99%

Are Brain-Computer Interfaces Feasible with Integrated Photonic Chips?

Salari¹,

Rodrigues²,

Sağlamyürek³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Coincidence imaging can be achieved with modern EMCCD cameras [31,32], SPAD arrays [33][34][35] or time stamping cameras [36]. These technologies are commonly exploited in quantum imaging, such as ghost imaging experiments [37][38][39][40] or quantum superresolution [41][42][43], as well as for fundamental applications, such as characterizing two-photon correlations [32,44], imaging of high-dimensional Hong-Ou-Mandel interference [45][46][47][48], and visualization of the violation of Bell inequalities [49]. Holography techniques have been recently proposed in the context of quantum imaging [50,51]; demonstrating the phaseshifting digital holography in a coincidence imaging regime using polarization entanglement [50], and exploiting induced coherence, i.e.…”

Section: Introductionmentioning

confidence: 99%

Interferometric imaging of amplitude and phase of spatial biphoton states

Zia¹,

Nazanin²,

D’Errico³

et al. 2023

Preprint

View full text Add to dashboard Cite

High-dimensional biphoton states are promising resources for quantum applications, ranging from highdimensional quantum communications to quantum imaging. A pivotal task is fully characterising these states, which is generally time-consuming and not scalable when projective measurement approaches are adopted. However, new advances in coincidence imaging technologies allow for overcoming these limitations by parallelising multiple measurements. Here, we introduce biphoton digital holography, in analogy to off-axis digital holography, where coincidence imaging of the superposition of an unknown state with a reference one is used to perform quantum state tomography. We apply this approach to single photons emitted by spontaneous parametric down-conversion in a nonlinear crystal when the pump photons possess various quantum states. The proposed reconstruction technique allows for a more efficient (3 order-of-magnitude faster) and reliable (an average fidelity of 87%) characterisation of states in arbitrary spatial modes bases, compared with previously performed experiments. Multi-photon digital holography may pave the route toward efficient and accurate computational ghost imaging and high-dimensional quantum information processing.

show abstract

Quantum Face Recognition Protocol with Ghost Imaging

Cited by 2 publications

References 24 publications

Are Brain-Computer Interfaces Feasible with Integrated Photonic Chips?

Are Brain-Computer Interfaces Feasible with Integrated Photonic Chips?

Interferometric imaging of amplitude and phase of spatial biphoton states

Contact Info

Product

Resources

About