Communication with Ambient Light using Digital Micromirror Devices

Research output: Contribution to journalConference articleScientificpeer-review

19 Downloads (Pure)

Abstract

Passive visible light communication (VLC) takes advantage of the pervasive nature of ambient light in our environment for wireless transmissions. The design of transmitters in passive VLC predominately uses liquid crystal displays (LCDs). While LCDs are an economical choice with low power consumption, they lack some key properties that are desirable for passive VLC. For example, LCDs absorb more than half of the incident light, leaving only a small portion to be used for communication. In addition, since the direction of ambient can change over time, the relative positions of the LCDs and receivers have to be changed constantly to maintain the correct alignment. To overcome these shortcomings, we propose the use of a novel transmitter with integrated optical fibres and digital micro-mirror devices (DMDs). DMDs are able to reflect up to 97% of the incident light, while the accompanying optical fibres aim to capture ambient light from various angles and guide them to the DMDs in a fixed direction. This design is a first step towards the goal of decoupling the direction of ambient light from the direction of the optical link, while achieving the same communication characteristics as LCDs with a much smaller device. We also design an App to allow users to easily interact with the system and our evaluation shows that the link can achieve a data rate of 1bps at a distance of 30cm.

Original languageEnglish
Number of pages4
JournalCEUR Workshop Proceedings
Volume2996
Publication statusPublished - 2021
Event2021 Workshops on Computer Human Interaction in IoT Applications, CHIIoT 2021 - Eindhoven, Netherlands
Duration: 8 Jun 20218 Jun 2021

Keywords

  • Digital Micromirror Device (DMD)
  • Passive communication
  • Visible light communication

Fingerprint

Dive into the research topics of 'Communication with Ambient Light using Digital Micromirror Devices'. Together they form a unique fingerprint.

Cite this