Characterization of Light-To-Frequency Converter for Visible Light Communication Systems

Martínez-Ciro, Roger Alexander; Giraldo, Francisco Eugenio López; Betancur-Pérez, Andrés F.; Rivera, Juan Pablo

doi:10.3390/electronics7090165

Cited by 15 publications

(17 citation statements)

References 17 publications

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“…For visible light communication, the published works focus on the devices, the physical-layer techniques, and system work aspects. In [20], the light-to-frequency converter for VLC is characterized. In [21,22], the physical-layer non-orthogonal multiple access and multi-color VLC, respectively, are addressed.…”

Section: The Present Issuementioning

confidence: 99%

Visible Light Communication and Positioning: Present and Future

Gong

2019

Electronics

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Section: The Present Issuementioning

confidence: 99%

Visible Light Communication and Positioning: Present and Future

Gong

2019

Electronics

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“…The dark frequency f D is generated by the LTF when irradiance is zero (E λ = 0) and it is also the result of leakage currents produced by the semiconductor material and affected by the temperature of the system [22]. The optical conversion gain R is given in (Hz/(µW/cm 2 )) and irradiance E λ = P in Ar is generated by the incident optical power P in and the photosensitive area of the photodiode Ar [19,23,24]. The irradiance units are given in µW/cm 2 .…”

Section: Ltf Timer Frequency Detectormentioning

confidence: 99%

“…The LTF was configured to operate at the maximum output frequency scale and only the channel with no filter was activated [30] to detect incident light optical power. In [19], an example illustrating the response of the LTF to an incident optical signal generated by a white light LED was shown. In order to measure the frequency generated by the LTF, at least half a period in high state is necessary to calculate its approximate value using a timer (depending on the resolution of the timer).…”

Section: Receivermentioning

confidence: 99%

“…This work was evaluated by means of Monte Carlo simulation, and it was shown that the process to implement the receiver was decreased by 66% compared to the one described in the standard IEEE 802.15.7 [16].Although CSK modulation is functional for high speed rates, in some scenarios with lower transmission speeds requirements, using an architecture based on ADC results in an oversized solution because they are more complex and expensive, and there are simpler solutions which are worth to implement. In this study, a simple and cost-effective VLC-CSK system with off-the-shelf components is proposed.The contribution of this work can be listed as it follows: (1) It proposes the study, analysis, and evaluation of a low-complexity VLC system by using CSK and a Light-To-Frequency (LTF) converter as a receiver [19]. (2) It proposes a particle swarm optimization (PSO) algorithm to design the M-CSK-LTF constellations that considers the euclidean distance between frequencies generated in the LTF and the restrictions of the transmitter and the receiver.…”

mentioning

confidence: 99%

“…The contribution of this work can be listed as it follows: (1) It proposes the study, analysis, and evaluation of a low-complexity VLC system by using CSK and a Light-To-Frequency (LTF) converter as a receiver [19]. (2) It proposes a particle swarm optimization (PSO) algorithm to design the M-CSK-LTF constellations that considers the euclidean distance between frequencies generated in the LTF and the restrictions of the transmitter and the receiver.…”

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Design and Implementation of a Multi-Colour Visible Light Communication System Based on a Light-to-Frequency Receiver

et al. 2019

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Colour-shift keying (CSK) is a visible light communication (VLC) modulation scheme used in the existing IEEE 802.15.7 standard. In CSK, information is transmitted by changing the light intensities of the RGB LEDs. In this work, a low-complexity VLC system is proposed using CSK modulation and a novel receiver based on a light-to-frequency (LTF) converter. At the receiver, CSK symbols are interpreted and decoded in terms of frequencies, which are processed by a counter module of a generic microcontroller, thus avoiding the use of analog-to-digital converters (ADCs), which results in a low-cost VLC system. The main contributions of this work are summarized in the following key points: (1) A low-complexity receiver for CSK modulation is introduced; (2) A particle swarm optimization (PSO) algorithm for CSK constellation design is suggested considering the restrictions of the LTF based receiver; (3) Experimental and theoretical validation is perfomed for the proposed multi-colour VLC system. The results show that this system can provide a transmission speed of 100 kbps using a 4-CSK-LTF constellation for a symbol error rate (SER) of 10 − 4 and a signal to noise ratio (SNR) around 35 dB. These results suggest that the analysed system could find applications on those scenarios where low transmission speeds and ease of deployment are the goals.

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Flexible Light‐to‐Frequency Conversion Circuits Built with Si‐Based Frequency‐to‐Digital Converters via Complementary Photosensitive Ring Oscillators with p‐Type SWNT and n‐Type a‐IGZO Thin Film Transistors

Jeong

Seo

et al. 2021

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In this study, as system‐level photodetectors, light‐to‐frequency conversion circuits (LFCs) are realized by i) photosensitive ring oscillators (ROs) composed of amorphous indium‐gallium‐zinc‐oxide/single‐walled carbon nanotube (a‐IGZO/SWNT) thin film transistors (TFTs) and ii) phase‐locked‐loop Si circuits built with frequency‐to‐digital converters (PFDC). The 3‐stage ROs and logic gates based on a‐IGZO/SWNT TFTs successfully demonstrate its performance on flexible substrates. Herein, along with the advantage of scalability, a‐IGZO films are used as photosensitive n‐type TFTs and SWNTs are employed as photo‐insensitive p‐type TFTs for better photosensitivity in circuit level. Through the controlling a post‐annealing condition of a‐IGZO film, responsivities and detectivities of a‐IGZO TFTs are obtained as 36 AW−1 and 0.3 × 1012 Jones for red, 93 AW−1 and 3.1 × 1012 Jones for green, and 194 AW–1 and 11.7 × 1012 Jones for blue. Furthermore, as an advanced demonstration for practical application of LFCs, a unique circuit (i.e., PFDC) is designed to analyze the generated oscillation frequency (fosc) from the LFC device and convert it to a digital code. As a result, the designed PFDC can exactly count the generated fosc from the flexible a‐IGZO/SWNT ROs under light illumination with an outstanding sensitivity and assign input frequencies to respective digital code.

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Characterization of Light-To-Frequency Converter for Visible Light Communication Systems

Cited by 15 publications

References 17 publications

Visible Light Communication and Positioning: Present and Future

Visible Light Communication and Positioning: Present and Future

Design and Implementation of a Multi-Colour Visible Light Communication System Based on a Light-to-Frequency Receiver

Flexible Light‐to‐Frequency Conversion Circuits Built with Si‐Based Frequency‐to‐Digital Converters via Complementary Photosensitive Ring Oscillators with p‐Type SWNT and n‐Type a‐IGZO Thin Film Transistors

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