Modulation light efficiency of diffractive lenses displayed in a restricted phase-mostly modulation display

Moreno, Ignacio; Iemmi, Claudio; Márquez, Andrés; Campos, Juan; Yzuel, María Josefa

doi:10.1364/ao.43.006278

Cited by 69 publications

(62 citation statements)

References 28 publications

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“…This modulation regime maximizes the modulation diffraction efficiency [10]. Many works have demonstrated in the past the usefulness of liquid crystal displays to act as phase-only spatial light modulators [11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Time fluctuations of the phase modulation in a liquid crystal on silicon display: characterization and effects in diffractive optics

Moreno¹,

Lizana²,

Márquez³

et al. 2008

Opt. Express

149

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Abstract:In this paper we provide evidence of the temporal fluctuations of the phase modulation property of a liquid crystal on silicon (LCoS) display, and we analyze its effect when the device is used for displaying a diffractive optical element. We use a commercial twisted nematic LCoS display configured to produce a phase-only modulation, and we provide time resolved measurements of the diffraction efficiency that show rapid fluctuations of the phase modulation, in the millisecond order. We analyze how these fluctuations have to be considered in two typical methods for the characterization of the phase modulation: two beam interference and diffraction from a binary grating. We finally provide experimental results on the use of this device for displaying a computer generated hologram. A reduction of the modulation diffraction efficiency results from the phase modulation fluctuation. Opt. Eng. 29, 240-246 (1990

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Section: Introductionmentioning

confidence: 99%

Time fluctuations of the phase modulation in a liquid crystal on silicon display: characterization and effects in diffractive optics

Moreno¹,

Lizana²,

Márquez³

et al. 2008

Opt. Express

149

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“…In digital holography applications, the diffraction efficiency is maximized when operating in the phase-only modulation regime (Moreno et al, 2004). Therefore, in such applications is very desirable to operate with an LCoS display response achieving a linear phase modulation up to 360 degrees, without coupled depolarization or coupled amplitude modulation.…”

Section: Lcos Display Optimizing Proceduresmentioning

confidence: 99%

Study of Liquid Crystal on Silicon Displays for Their Application in Digital Holography

Lizana¹,

Lobato²,

Márquez³

et al. 2011

Advanced Holography - Metrology and Imaging

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“…The aforementioned procedures were complemented with a convenient choice of the grating period and orientation [42] and an appropriate configuration of the SLM-i.e. phase modulation response to the addressed gray levels [43] and digital electric addressing sequences [44]-in order to improve the efficiency and temporal stability of the modulated phase. Figure 5 shows an example of |t(x, y)|, Arg(t(x, y)) and the corresponding phase masks addressed at the SLM (via PA or GD method) used to prepare a given spatial qudit state with D = 7.…”

mentioning

confidence: 99%

Experimental Minimum-Error Quantum-State Discrimination in High Dimensions

et al. 2017

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Quantum mechanics forbids perfect discrimination among nonorthogonal states through a single shot measurement. To optimize this task, many strategies were devised that later became fundamental tools for quantum information processing. Here, we address the pioneering minimum-error (ME) measurement and give the first experimental demonstration of its application for discriminating nonorthogonal states in high dimensions. Our scheme is designed to distinguish symmetric pure states encoded in the transverse spatial modes of an optical field; the optimal measurement is performed by a projection onto the Fourier transform basis of these modes. For dimensions ranging from D = 2 to D = 21 and nearly 14000 states tested, the deviations of the experimental results from the theoretical values range from 0.3% to 3.6% (getting below 2% for the vast majority), thus showing the excellent performance of our scheme. This ME measurement is a building block for high-dimensional implementations of many quantum communication protocols, including probabilistic state discrimination, dense coding with nonmaximal entanglement, and cryptographic schemes.Quantum mechanics establishes fundamental bounds to our capability of distinguishing among states with nonvanishing overlap: if one is given at random one of two or more nonorthogonal states and asked to identify it from a single shot measurement, it will be impossible to accomplish the task deterministically and with full confidence. This constraint has deep implications both foundational, underlying the debate about the epistemic and ontic nature of quantum states [1][2][3][4], and practical, warranting secrecy in quantum key distribution [5,6]. Beyond that, the problem of discriminating nonorthogonal quantum states plays an important role in quantum information and quantum communications [7].A wide variety of measurement strategies have been devised in order to optimize the state discrimination process according to a predefined figure of merit [7]. The pioneering one was the minimum-error (ME) measurement [8][9][10] where each outcome identifies one of the possible states and the overall error probability is minimized. Other fundamental strategies conceived later [11][12][13][14][15][16][17] employ the ME discrimination in the step next to a transformation taking the input states to more distinguishable ones [18], which enables us to identify them with any desired confidence level (within the allowed bounds) and a maximum success probability. Nowadays, the ME measurement is central to a range of applications, including quantum imaging [19], quantum reading [20], image discrimination [21], error correcting codes [22], and quantum repeaters [23], thus stressing its importance.Closed-form solutions for ME measurements are known only for a few sets of states. One of these is the set of symmetric pure states (defined below) prepared with equal * msolisp@udec.cl † lneves@fisica.ufmg.br prior probabilities [24]. Discriminating among them with minimum error sets the bounds on the eavesdropping...

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Modulation light efficiency of diffractive lenses displayed in a restricted phase-mostly modulation display

Cited by 69 publications

References 28 publications

Time fluctuations of the phase modulation in a liquid crystal on silicon display: characterization and effects in diffractive optics

Time fluctuations of the phase modulation in a liquid crystal on silicon display: characterization and effects in diffractive optics

Study of Liquid Crystal on Silicon Displays for Their Application in Digital Holography

Experimental Minimum-Error Quantum-State Discrimination in High Dimensions

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