More Like this

1. Swazure: Swarm Measurement of Pose for Flying Light Specks

   https://doi.org/10.61981/ZFSH2403  

   Alimohammadzadeh, Hamed; Ghandeharizadeh, Shahram (December 2024, Mitra LLC)

   One may construct a 3D multimedia display using miniature drones configured with light sources, Flying Light Specks (FLSs). Swarms of FLSs localize to illuminate complex 3D shapes and animated sequences. This requires FLSs to measure their relative pose (distance and angle) accurately. A challenge is how to do this when the sensors used by FLSs have a blind range that prevents them from quantifying their relative pose. Our technique, Swazure, requires FLSs to cooperate to compensate for their sensor's blind range. It implements {\em physical data independence} by abstracting the physical characteristics of the sensors, making point cloud data independent of the sensor hardware. The size of an FLS relative to the minimum distance between points of a point cloud is an important parameter. It may result in potential obstructions that prevent Swazure from quantifying relative pose. We present two techniques, move obstructing and move source, to address this limitation. Our experimental results show the superiority of the Move Obstructing technique. 

   more » « less
2. Swarical: An Integrated Hierarchical Approach to Localizing Flying Light Specks

   https://doi.org/10.1145/3664647.3681080  

   Alimohammadzadeh, Hamed; Ghandeharizadeh, Shahram (October 2024, ACM)

   Swarical, a Swarm-based hierarchical localization technique, enables miniature drones, Flying Light Specks (FLSs), to accurately and efficiently localize and illuminate complex 2D and 3D shapes. Its accuracy depends on the physical hardware (sensors) of FLSs used to track neighboring FLSs to localize themselves. It uses the specification of the sensors to convert mesh files into point clouds that enable a swarm of FLSs to localize at the highest accuracy afforded by their sensors. Swarical considers a heterogeneous mix of FLSs with different orientations for their tracking sensors, ensuring a line of sight between a localizing FLS and its anchor FLS. We present an implementation using Raspberry cameras and ArUco markers. A comparison of Swarical with a state of the art decentralized localization technique shows that it is as accurate and more than 2x faster. 

   more » « less
3. SwarMer: A Decentralized Localization Framework for Flying Light Specks

   Alimohammadzadeh H.; Ghandeharizadeh S. (December 2023, First International Conference on Holodecks)

   Ghandeharizadeh S. (Ed.)

   Swarm-Merging, SwarMer, is a decentralized framework to localize Flying Light Specks (FLSs) to render 2D and 3D shapes. An FLS is a miniature sized drone equipped with one or more light sources to generate different colors and textures with adjustable brightness. It is battery powered, network enabled with storage and processing capability to implement a decentralized algorithm such as SwarMer. An FLS is unable to render a shape by itself. SwarMer uses the inter-FLS relationship effect of its organizational framework to compensate for the simplicity of each individual FLS, enabling a swarm of cooperating FLSs to render complex shapes. SwarMer is resilient to network packet loss, FLSs failing, and FLSs leaving to charge their battery. It is fast, highly accurate, and scales to remain effective when a shape consists of a large number of FLSs. 

   more » « less
4. Techniques to Conceal Dark Standby Flying Light Specks

   https://doi.org/10.1145/3724399  

   Alimohammadzadeh, Hamed; Zhu, Shuqin; Ghandeharizadeh, Shahram (April 2025, ACM Transactions on Multimedia Computing, Communications, and Applications)

   A Flying Light Speck, FLS, is a small drone configured with light sources to illuminate different colors and textures. A swarm of FLSs illuminates complex 3D multimedia shapes in a fixed volume, a 3D display. An FLS is a mechanical device. Its failure is the norm rather than an exception, causing a point of an illumination to go dark. In this paper, we use reliability groups with dark standby FLSs to minimize the duration of time a point remains dark. We introduce three techniques to prevent a dark standby FLS from obstructing the user’s field of view, FoV. All three move the FLS out of the user’s FoV. One technique, Suspend:Closest, maximizes the utility of a standby FLS while preventing it from obstructing the user’s FoV. 

   more » « less
5. An Evaluation of Decentralized Group Formation Techniques for Flying Light Specks

   https://doi.org/10.1145/3595916.3626460  

   Alimohammadzadeh, Hamed; Culbertson, Heather; Ghandeharizadeh, Shahram (December 2023, ACM)

   Group formation is fundamental for 3D displays that use Flying Light Specks, FLSs, to illuminate shapes and provide haptic interactions. An FLS is a drone with light sources that illuminates a shape. Groups of G FLSs may implement reliability techniques to tolerate FLS failures, provide kinesthetic haptic feedback in response to a user’s touch, and facilitate a divide and conquer approach to challenges such as localizing FLSs to render a shape. This paper evaluates four decentralized techniques to form groups. An FLS implements a technique autonomously using asynchronous communication and without a global clock. We evaluate these techniques using synthetic point clouds with known optimal solutions and real point clouds. Obtained results show a technique named Random Subset (RS) is superior when constructing small groups (G ≤ 5) while a different technique named Closest Available Neighbor First (CANF) is superior when constructing large groups (G ≥ 10). 

   more » « less