Enhancement factor in wavefront shaping depends on the spatial resolution of a spatial light modulator (SLM) and on the modulation type. For a given resolution, phase modulation provides better enhancement than amplitude modulation, and thus is more preferable. In order to make wavefront shaping practical, it is important to provide the highest possible refresh rate of SLM. Liquid crystal SLMs are known for their outstanding phase modulation capabilities but their speed usually does not exceed a few hundred hertz. Meanwhile, digital micromirror devices (DMDs) can reach the refresh rates of 20 kHz that meets demands of practical applications. Although the refresh rate is high, this kind of the SLM can operate only in binary amplitude mode. In this paper we consider conversion of binary amplitude modulation into phase modulation by removal of zero spatial frequency from the modulated beam with respect to the application in wavefront shaping. We demonstrate experimentally increasing enhancement factor in 1.5 times (theoretically up to 2-fold). The advantage of considered method is its simplicity as it requires only a telescopic system and a simple spatial filter. In our case, it did not require any modification of the existing setup except the addition of the removable filter. Also, the considered method is suitable for any kind of spatial light modulator and is not limited to DMD. The obvious benefit of the modulation conversion is that we can use fewer modes to achieve the same enhancement factor and thus increase the focusing speed.
Wavefront shaping technique makes it possible to overcome limitations for optical imaging in strongly scattering media. Various wavefront shaping algorithms are used in order to find an optimal incident optical field. However, in many cases such experiments appear to be very time consuming and suffer from instability of the scattering media. So, it seems reasonable to use computer simulation in this field. In this paper we use two different approaches to simulate the light focusing through scattering media. The first approach consists in numerical solution of Maxwell equations for the set of spherical particles in random positions, which represent the scattering media. The result of the solution represents the scattering matrix of the media. This matrix is used to simulate propagation of spatially modulated light in the “frozen” stochastic media. As entries of the scattering matrix appear to be random variables with Gaussian distribution, they could be set heuristically for modeling purposes. This makes possible modeling of the wavefront shaping with large number of orthogonal modes of incident light. We considered four focusing techniques: continuous sequential algorithm and focusing using useful properties of Hadamard matrix with a phase-only and binary amplitude modulation (BAM). We represent results on convergence of the algorithms and focal intensity enhancement. We examined spatial variations of intensity enhancement, while scanning the focal point in observation plane. We found, that the intensity enhancement strongly correlates with the speckle from unmodulated illumination, when the BAM is used for wavefront shaping. In the case of phase-only modulation, only weak correlations were observed.
The present study is concerned with wavefront shaping algorithms and their performance in noisy environments. Simple sequential algorithms has quite low initial enhancement rate which makes it hard to overcome strong noise. As a result, more complex algorithms which use multiple spatial light modulator pixels were developed. It made it possible to overcome noise at the initial stage faster. One of such algorithms is the partitioning algorithm. The maximum length sequence algorithm considered in this paper is proposed as an improvement of the partitioning algorithm. Both algorithms have similar initial enhancement rates but the proposed one keeps higher rate also at later stages.
The present study considers ab initio computer simulation of the light focusing through a complex scattering medium. The focusing is performed by shaping the incident light beam in order to obtain a small focused spot on the opposite side of the scattering layer. MSTM software (Auburn University) is used to simulate the propagation of an arbitrary monochromatic Gaussian beam and obtain 2D distribution of the optical field in the selected plane of the investigated volume. Based on the set of incident and scattered fields, the pair of right and left eigen bases and corresponding singular values were calculated. The pair of right and left eigen modes together with the corresponding singular value constitute the transmittance eigen channel of the disordered media. Thus, the scattering process is described in three steps: 1) initial field decomposition in the right eigen basis; 2) scaling of decomposition coefficients for the corresponding singular values; 3) assembling of the scattered field as the composition of the weighted left eigen modes. Basis fields are represented as a linear combination of the original Gaussian beams and scattered fields. It was demonstrated that 60 independent control channels provide focusing the light into a spot with the minimal radius of approximately 0.4 μm at half maximum. The intensity enhancement in the focal plane was equal to 68 that coincided with theoretical prediction.
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