Generating Airborne Ultrasonic Amplitude Patterns Using an Open Hardware Phased Array

Morales, Rafael; Ezcurdia, Iñigo; Irisarri, Josu; Andrade, Marco A. B.; Marzo, Asier

doi:10.3390/app11072981

Cited by 29 publications

(15 citation statements)

References 50 publications

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“…This setup uses two opposed arrays of 16×16 transducers controlled by an FPGA and an OptiTrack tracking system (Prime 13 motion capture system at a frequency of 240Hz). The design of the arrays is a reproduction of the setup in [Morales et al 2021], modified to operate at 20Vpp and higher update rates of 10kHz. The device generates a single twintrap using the method described in [Hirayama et al 2019], allowing for vertical and horizontal forces of 4.2 • 10 −5 N and 2.1 • 10 −5 N, respectively, experimentally computed using the linear speed tests in [Hirayama et al 2019] (i.e., 10cm paths, binary search with 9 out 10 success ratios, with particle mass 𝑚 ≈ 0.7 • 10 −7 kg).…”

Section: Modelling the Trap-particle Dynamicsmentioning

confidence: 99%

OptiTrap: Optimal Trap Trajectories for Acoustic Levitation Displays

et al. 2022

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Acoustic levitation has recently demonstrated the ability to create volumetric content by trapping and quickly moving particles along reference paths to reveal shapes in mid-air. However, the problem of specifying physically feasible trap trajectories to display desired shapes remains unsolved. Even if only the final shape is of interest to the content creator, the trap trajectories need to determine where and when the traps need to be, for the particle to reveal the intended shape. We propose OptiTrap , the first structured numerical approach to compute trap trajectories for acoustic levitation displays. Our approach generates trap trajectories that are physically feasible and nearly time-optimal, and reveal generic mid-air shapes, given only a reference path (i.e., a shape with no time information). We provide a multi-dimensional model of the acoustic forces around a trap to model the trap-particle system dynamics and compute optimal trap trajectories by formulating and solving a non-linear path following problem. We formulate our approach and evaluate it, demonstrating how OptiTrap consistently produces feasible and nearly optimal paths, with increases in size, frequency, and accuracy of the shapes rendered, allowing us to demonstrate larger and more complex shapes than ever shown to date.

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Section: Modelling the Trap-particle Dynamicsmentioning

confidence: 99%

OptiTrap: Optimal Trap Trajectories for Acoustic Levitation Displays

et al. 2022

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“…Initially, the acoustic focus, which forms the basis for mid-air haptics, was amplitude modulated (AM) to create a localized vibrotactile sensation, while later the focus was moved around in space to create small lateral modulations (LM) [8] or to trace out larger tactile shapes using so-called Spatio-temporal modulation (STM) [9]. Techniques that use acoustic holography [10], multiple focal points [11], or a blend of AM and STM [12] have also emerged and appear to be more suitable at delivering different haptic sensations in different settings. However, none of these modulation techniques adapt or take into consideration the heterogeneity of the human skin, the density, and types of mechanoreceptors being targeted, nor any effects of wave interference on the skin surface [13].…”

Section: Haptic Sensations and Rendering Algorithmsmentioning

confidence: 99%

Mid-Air Haptics: Future Challenges and Opportunities

Georgiou

Frier

Freeman

et al. 2022

Ultrasound Mid-Air Haptics for Touchless Interfaces

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Ultrasound mid-air haptic technology has advanced in many ways over the past decade and has found meaningful application in a plethora of use cases. As the technology matures further and progresses from lab to market, in this chapter, we take a step back and discuss three specific directions that we think could result in the greatest impact. Namely, we highlight challenges and opportunities in improving (1) the hardware platforms used, (2) the rendering algorithms employed to create rich haptic sensations, and (3) the resulting user experience and added value the technology can instill to different end-user applications. We hope that this "wishlist" inspires the mid-air haptics and human computer interaction (HCI) community and others to join our efforts toward a deeper technology understanding, integration, and readiness.

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“…If the desired image size is set too large, the paraxial approximation will not be satisfied or the information content [21] of the hologram will be less than that of the image. Therefore, in general, for acoustic holographic imaging, the desired image size is set to be equal to or similar to the hologram size in most research [3,[15][16][17][18][19][21][22][23][24][25][26][27][28].…”

Section: Selection Of Geometric Parametersmentioning

confidence: 99%

“…Due to its powerful and flexible capability of arbitrary sound beam shaping and predesigned sound field reconstruction, acoustic holography has recently received increased attention in many interdisciplinary fields related to acoustics, including medicine [3][4][5][6], engineering [7,8], and biology [9][10][11], in addition to the pure acoustic field. Many applications have been made possible by acoustic holography, including acoustic fabrication [7], beam shaping [12][13][14][15][16][17][18][19][20], acoustic holographic imaging [3,[15][16][17][18][19][20][21][22][23][24][25][26][27][28], volumetric display [29,30], volumetric haptics [31,32], particle manipulation [11,21,26,33,34], 3D ultrasound imaging [8], cell manipulation [9,10], characterizing medical ultra...…”

Section: Introductionmentioning

confidence: 99%

“…The algorithms used include the iterative angular spectrum approach [21], the iterative backpropagation algorithm [33], the weighted Gerchberg-Saxton algorithm [20], the pseudo-inverse method [36], the conjugate field method [37], the deep learning method [35], and so on. Physically, these calculated maps are realized by either discrete and independently driven elements of active phasedarray emitters [3][4][5][27][28][29][30][31][32][33][34] (such as loudspeakers in the air or piezoelectric transducers in 2 of 13 water) or meta-pixels of passive acoustic metasurfaces [6][7][8][9][12][13][14][15][16][17][18][19][20][21][22][23][24][25]38], or a combination of both [26]. In the reconstruction process, these acoustic holographic devices with the required phase and/or amplitude distributions diffract sound waves to form the desired real image in the pre-designed image plane.…”

Section: Introductionmentioning

confidence: 99%

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Theoretical Zero-Thickness Broadband Holograms Based on Acoustic Sieve Metasurfaces

Tian

Zuo

et al. 2022

Applied Sciences

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Acoustic holography is an essential tool for controlling sound waves, generating highly complex and customizable sound fields, and enabling the visualization of sound fields. Based on acoustic sieve metasurfaces (ASMs), this paper proposes a theoretical design approach for zero-thickness broadband holograms. The ASM is a zero-thickness rigid screen with a large number of small holes that allow sound waves to pass through and produce the desired real image in the target plane. The hole arrangement rules are determined using a genetic algorithm and the Rayleigh–Sommerfeld theory. Because the wave from a hole has no extra phase or amplitude modulation, the intractable modulation dispersion can be physically avoided, allowing the proposed ASM-based hologram to potentially function in any frequency band as long as the condition of paraxial approximation is satisfied. Using a numerical simulation based on the combination of the finite element method (FEM) and the boundary element method (BEM), this research achieves broadband holographic imaging with a good effect. The proposed theoretical zero-thickness broadband hologram may provide new possibilities for acoustic holography applications.

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Generating Airborne Ultrasonic Amplitude Patterns Using an Open Hardware Phased Array

Cited by 29 publications

References 50 publications

OptiTrap: Optimal Trap Trajectories for Acoustic Levitation Displays

OptiTrap: Optimal Trap Trajectories for Acoustic Levitation Displays

Mid-Air Haptics: Future Challenges and Opportunities

Theoretical Zero-Thickness Broadband Holograms Based on Acoustic Sieve Metasurfaces

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