Your search keyword '"Arulandu A"' showing total 10 results

1. Modeling and analysis of transmitter performance in visible light communications

Author

Yan Wu, Kumar Arulandu, Guofu Zhou, Xiong Deng, Jean-Paul M. G. Linnartz, Shokoufeh Mardanikorani, Signal Processing Systems, Stimuli-responsive Funct. Materials & Dev., Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

VLC, driver, Computer Networks and Communications, Orthogonal frequency-division multiplexing, Computer science, Aerospace Engineering, Visible light communication, law.invention, Amplitude modulation, Bias tee, law, Electronic engineering, Electrical and Electronic Engineering, Computer Science::Information Theory, Common emitter, OFDM, communication, Transmitter, LED, power consumption, transmitter, Illumination, Modulation, Pulse-amplitude modulation, efficiency, Automotive Engineering, Bit error rate, PAM, Light-emitting diode

Abstract

This work addresses the power penalty in a Visible Light Communication (VLC) emitter that re-uses illumination Light Emitting Diodes (LEDs) for high-speed communications. We quantify the effect of modulation depth for two widely explored modulation schemes in VLC, namely Orthogonal Frequency Division Multiplexing (OFDM) and Pulse Amplitude Modulation (PAM). Extra power is dissipated in the LED and in the modulator due to such modulation. Two popular highspeed VLC transmitter topologies, namely a Bias Tee (Bias-T) and a Serial FET (Serial-F), are compared in terms of efficiency, Extra Energy Per Symbol/Bit (EEPS/B) and complexity. This work presents a theoretical model and compares it to simulationresults. We show that PAM outperforms OFDM in terms of better Bit Error Rate (BER), larger dynamic range for modulation depth, less extra power loss, thus higher power efficiency for communication over an Additive White Gaussian Noise (AWGN) channel.

Published

2019

2. Enhanced visible light communication modulators with dual feedback control

Author

Xiong Deng, Kumar Arulandu, Jean-Paul M. G. Linnartz, Signal Processing Systems, Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

Computer science, Energy Engineering and Power Technology, Visible light communication, Throughput, Topology (electrical circuits), Field effect transistors, Switched mode power supplies, Topology, optical wireless communication (OWC), Bandwidth, visible light communication (VLC), Electronic engineering, Electrical and Electronic Engineering, OFDM, Modulation, Communication, illumination, Bandwidth (signal processing), LED, modulator, Light emitting diodes, Power (physics), Optical wireless, Constant current, control

Abstract

This article presents a modulator for optical wireless communication (OWC) via LEDs, controlled by a dual closed loop. While the potential communication speed and performance of OWC have received a lot of research attention, the design of appropriate modulator circuits has not been studied so widely. This article addresses the control aspects to minimize power losses and to ensure automatic adaptation to component spreads or aging, for “high-power” LED emitters. We initially address a “low-bandwidth– system, particularly suited for indoor camera-based detection, and then a “higher bandwidth” one for Li-Fi data communication. In contrast to maximizing data throughput as it applies to high-speed modulators, low-speed modulators aim at high power and high efficiency in general lighting applications. Specifically, for the high-power modulator, we propose a control strategy that allows a wide range of combinations of LED types and LED power supplies. The power consumption of the modulator is minimized by voltage margin setting that is automatically adapt to the modulation and the LED type using the nonlinear detector. The common industry practice is to use constant-current LED drivers for powering LEDs. After creating a theoretical framework of some generality to evaluate designs and control loops with rationals and verified models, we realize modulator designs that are supplied by constant current LED drivers and verify their performance by simulation and measurements.

Published

2021

3. Mitigating LED nonlinearity to enhance visible light communications

Author

Bin Chen, Shokoufeh Mardanikorani, Xiong Deng, Kumar Arulandu, Jean-Paul M. G. Linnartz, A. M. Khalid, Yan Wu, Signal Processing Systems, Electro-Optical Communication, Information and Communication Theory Lab, Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

bandwidth, VLC, Photon, Computer science, channel capacity, Charge carrier processes, Visible light communication, 02 engineering and technology, Multiplexing, law.invention, 020210 optoelectronics & photonics, Mathematical model, law, Radiative recombination, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Spontaneous emission, Transient response, Electrical and Electronic Engineering, Lighting, BER, communication, illumination, Bandwidth (signal processing), LED, nonlinearity, Keying, Light emitting diodes, Nonlinear system, Amplitude, Pulse-amplitude modulation, equalization, Light-emitting diode

Abstract

This paper addresses the nonlinear memory effects in the response of typical illumination light emitting diodes (LEDs), in order to enhance the performance of visible light communication (VLC) systems. These LEDs have a limited bandwidth of only several MHz. To reflect the physical mechanisms in the quantum well, we describe the LED transient response by a nonlinear dynamic differential equation. Three different mechanisms of the nonlinearity are relevant in the double hetero-structure LEDs, which result in dynamic nonlinearities, that is, a mixture of nonlinearities and memory effects. Hitherto, generic pre-distorter and non-linear equalizers have been studied for the LEDs. Yet this paper shows that recombination rates of photon generation can be translated into an equivalent discrete-time circuit that can be inverted. This allows us to develop a new pre-distorter with a simpler and more efficient structure than previously studied and overly generic approaches. The novel pre-distorter along with a parameter estimation can effectively overcome LED nonlinearity for high-speed VLC with amplitude-based single carrier modulations, including ON-OFF keying and pulse amplitude modulation-4 systems, and with the multi-carrier orthogonal frequency-division multiplexing. We report experimentally obtained eye-diagrams, first to justify our choice for the LED model on which our nonlinear pre-distorter have been based, and second to verify the effectiveness in enhancing the VLC link performance to the extent predicted by our model.

Published

2018

4. Novel post-distortion to mitigate LED nonlinearity in high-speed visible light communications

Author

Kumar Arulandu, Shokoufeh Mardanikorani, Xiong Deng, Jean-Paul M. G. Linnartz, Signal Processing Systems, Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

bandwidth, VLC, Computer science, Visible light communication, Optical power, 02 engineering and technology, law.invention, 020210 optoelectronics & photonics, law, 0202 electrical engineering, electronic engineering, information engineering, Spontaneous emission, Voltage droop, Transient response, business.industry, communication, illumination, Bandwidth (signal processing), LED, Nonlinear optics, nonlinearity, Nonlinear system, Pulse-amplitude modulation, Optoelectronics, business, data rate, equalization, Light-emitting diode

Abstract

This paper addresses dynamic nonlinear effects in the response of typical illumination Light Emitting Diodes (LEDs) to increase the reliability and data rate in Visible Light Communication (VLC) systems. These power LEDs have a limited bandwidth of only several MHz. To conceive a practical receiver, we describe the LED transient response by a nonlinear dynamic differential equation from the physical mechanisms in the Quantum Well (QW) of Double Hetero-structured (DH) LEDs. It includes the transient nonlinear relation between the input current and injection electron concentration, as governed by the dynamic rate equation. Also, we consider the static nonlinear (typically quadratic) relation between the injection electron concentration and output optical power is described by a square operator. Further we consider the static nonlinear relation between the injection current and output optical power, caused by the efficiency droop. We propose a novel post-distorter to overcome LED nonlinearities for high-speed Pulse Amplitude Modulation (PAM)-4 systems. Its performance is validated with measurements of a commercial blue LED.

Published

2019

5. Dynamic response-based LEDs health and temperature monitoring

Author

Jean-Paul M. G. Linnartz, Kumar Arulandu, Anton Alexeev, Grigory Onushkin, Genevieve Martin, Signal Processing Systems, Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

Computer science, Visible light communication, Gallium nitride, 02 engineering and technology, Smart driver, Failure modes, 01 natural sciences, Predictive maintenance, law.invention, chemistry.chemical_compound, law, OWC, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, Electrical response, Instrumentation, Electrical impedance, Diode, Optical response, Applied Mathematics, LED, 020208 electrical & electronic engineering, 010401 analytical chemistry, Temperature, Impedance, Reliability, Condensed Matter Physics, 0104 chemical sciences, Solid-state lighting, chemistry, Defects, Junction temperature, Light-emitting diode

Abstract

This paper presents a number of novel methods to measure the junction temperature and to estimate the health of gallium nitride light-emitting diodes (LEDs). The methods are based on measurements of the dynamic impedance and optical output. Our experimental analysis reveals temperature sensitive parameters of the electrical and optical responses. Moreover, a correlation between the non-radiative current characterizing the active region defects and the small-signal impedance is shown. The demonstrated methods can be applied to enhance existing temperature-monitoring techniques. The derived dependencies also build a foundation for advanced in-field health monitoring of the LEDs using the infrastructure of visible light communication systems. Such methods and techniques are valuable for predictive maintenance of solid state lighting systems.

Published

2020

6. Performance analysis for joint illumination and visible light communication using buck driver

Author

Jean-Paul M. G. Linnartz, Yan Wu, Kumar Arulandu, Guofu Zhou, Xiong Deng, Signal Processing Systems, Lighting and IoT Lab, and Center for Wireless Technology Eindhoven

Subjects

VLC, driver, Computer science, Ripple, Visible light communication, 02 engineering and technology, Interference (wave propagation), law.invention, Amplitude modulation, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, BER, Buck converter, communication, illumination, ripple, 020208 electrical & electronic engineering, LED, Shot noise, 020206 networking & telecommunications, power consumption, BPM, Modulation, Duty cycle, efficiency, Bit error rate, Phase modulation, buck converter, Light-emitting diode, Data transmission

Abstract

The visible light communication (VLC) can provide data transmission via the illumination light emitting diodes (LED). This paper introduces a new model to analyze the bit error rate (BER) of binary phase modulation in VLC for an arbitrary modulation depth and data duty cycle while taking into account both the Gaussian and signal-dependent shot noise. The impact of the driver design on the BER and its impact on ripple have not been considered in detail before. We compare two different LED driver schemes, namely directly adapting the driver control loop and binary shunting. We address data rate, BER, and power efficiency, for which we propose to use the extra energy per symbol above unmodulated light. We further introduce an analysis of the effect that (truncated) ripple interference has in the (matched or other) filter of the receiver. Ripple causes a harmful interference in VLC, and thus a BER expression is derived to include its effect. Two approximations are proposed to model the ripple interference, and their accuracies are compared by simulations. A low-pass filtering is proposed to alleviate the impact of ripple interference in VLC system.

Published

2018

7. Modeling and Analysis of Transmitter Performance in Visible Light Communications.

Author

Xiong Deng, Arulandu, Kumar, Yan Wu, Mardanikorani, Shokoufeh, Guofu Zhou, and Linnartz, Jean-Paul M. G.

Subjects

*LIGHT emitting diodes, *TRANSMITTERS (Communication), *VISIBLE spectra, *ORTHOGONAL frequency division multiplexing, *RANDOM noise theory

Abstract

This paper addresses the power penalty in a visible light communication (VLC) emitter that re-uses illumination light emitting diodes (LEDs) for high-speed communications. We quantify the effect of modulation depth for two widely explored modulation schemes in VLC, namely orthogonal frequency division multiplexing (OFDM) and pulse amplitude modulation (PAM). Extra power is dissipated in the LED and in the modulator due to such modulation. Two popular high-speed VLC transmitter topologies, namely a Bias Tee and a Serial FET, are compared in terms of efficiency, extra energy per symbol/bit and complexity. This paper presents a theoretical model and compares it to simulation results. We show that PAM outperforms OFDM in terms of better bit error rate, larger dynamic range for modulation depth, less extra power loss, thus higher power efficiency for communication over an additive white Gaussian noise channel. [ABSTRACT FROM AUTHOR]

Published

2019

8. Mitigating LED Nonlinearity to Enhance Visible Light Communications.

Author

Deng, Xiong, Mardanikorani, Shokoufeh, Wu, Yan, Arulandu, Kumar, Chen, Bin, Khalid, Amir M., and Linnartz, Jean-Paul M. G.

Subjects

VISIBLE spectra, OPTICAL communications, LED lighting, QUANTUM wells, DIFFERENTIAL equations

Abstract

This paper addresses the nonlinear memory effects in the response of typical illumination light emitting diodes (LEDs), in order to enhance the performance of visible light communication (VLC) systems. These LEDs have a limited bandwidth of only several MHz. To reflect the physical mechanisms in the quantum well, we describe the LED transient response by a nonlinear dynamic differential equation. Three different mechanisms of the nonlinearity are relevant in the double hetero-structure LEDs, which result in dynamic nonlinearities, that is, a mixture of nonlinearities and memory effects. Hitherto, generic pre-distorter and non-linear equalizers have been studied for the LEDs. Yet this paper shows that recombination rates of photon generation can be translated into an equivalent discrete-time circuit that can be inverted. This allows us to develop a new pre-distorter with a simpler and more efficient structure than previously studied and overly generic approaches. The novel pre-distorter along with a parameter estimation can effectively overcome LED nonlinearity for high-speed VLC with amplitude-based single carrier modulations, including ON–OFF keying and pulse amplitude modulation-4 systems, and with the multi-carrier orthogonal frequency-division multiplexing. We report experimentally obtained eye-diagrams, first to justify our choice for the LED model on which our nonlinear pre-distorter have been based, and second to verify the effectiveness in enhancing the VLC link performance to the extent predicted by our model. [ABSTRACT FROM AUTHOR]

Published

2018

9. Performance Analysis for Joint Illumination and Visible Light Communication Using Buck Driver.

Author

Deng, Xiong, Arulandu, Kumar, Wu, Yan, Zhou, Guofu, and Linnartz, Jean-Paul M. G.

Subjects

*VISIBLE spectra, *OPTICAL communications, *WIRELESS communications, *DATA transmission systems, *LIGHT emitting diodes, *BIT error rate, *BINARY control systems, *PHASE modulation

Abstract

The visible light communication (VLC) can provide data transmission via the illumination light emitting diodes (LED). This paper introduces a new model to analyze the bit error rate (BER) of binary phase modulation in VLC for an arbitrary modulation depth and data duty cycle while taking into account both the Gaussian and signal-dependent shot noise. The impact of the driver design on the BER and its impact on ripple have not been considered in detail before. We compare two different LED driver schemes, namely directly adapting the driver control loop and binary shunting. We address data rate, BER, and power efficiency, for which we propose to use the extra energy per symbol above unmodulated light. We further introduce an analysis of the effect that (truncated) ripple interference has in the (matched or other) filter of the receiver. Ripple causes a harmful interference in VLC, and thus a BER expression is derived to include its effect. Two approximations are proposed to model the ripple interference, and their accuracies are compared by simulations. A low-pass filtering is proposed to alleviate the impact of ripple interference in VLC system. [ABSTRACT FROM PUBLISHER]

Published

2018

10. Dynamic response-based LEDs health and temperature monitoring.

Author

Alexeev, Anton, Linnartz, Jean-Paul, Onushkin, Grigory, Arulandu, Kumar, and Martin, Genevieve

Subjects

*OPTICAL communications, *TELECOMMUNICATION systems, *VISIBLE spectra, *TEMPERATURE

Abstract

• We demonstrated new indicators of GaN LED temperature. • We have found highly sensitive GaN LED temperature predictors. • We demonstrated new indicator of LED health and imminent failures. This paper presents a number of novel methods to measure the junction temperature and to estimate the health of gallium nitride light-emitting diodes (LEDs). The methods are based on measurements of the dynamic impedance and optical output. Our experimental analysis reveals temperature sensitive parameters of the electrical and optical responses. Moreover, a correlation between the non-radiative current characterizing the active region defects and the small-signal impedance is shown. The demonstrated methods can be applied to enhance existing temperature-monitoring techniques. The derived dependencies also build a foundation for advanced in-field health monitoring of the LEDs using the infrastructure of visible light communication systems. Such methods and techniques are valuable for predictive maintenance of solid state lighting systems. [ABSTRACT FROM AUTHOR]

Published

2020