Sage Journals: Discover world-class research

Abstract

Existing colour gamut metrics for solid-state lighting and displays are typically three-dimensional descriptions that do not explicitly capture how chromatic boundaries change under electrical and thermal operating conditions. Consequently, there is a lack of quantitative understanding of two-dimensional (2D) colour gamut behaviour of RGB LED devices as a function of driving current and device temperature. This work bridges the gap by experimentally mapping the 2D colour gamut boundaries of RGB LED pixels across current and temperature ranges and proposing a model that links operating conditions to observed gamut shifts. These operating conditions are optimized by simultaneously maximizing the 2D colour gamut area and the wall-plug efficiency via a multi-objective scaled merit function. Furthermore, integrating of RGB LEDs with an added white LED (RGBW system) enabled dynamic correlated colour temperature regulation from 2000 K to 9000 K under the tested conditions, via adjustment of the white-LED drive current with compensatory RGB currents and device temperature. The 2D colour gamut variation exhibits a strong dependence on white-LED compensation, shifting from minor to significantly under specified conditions. Given this strong dependence, a novel multi-physical model integrating electrical, thermal and optical characteristics was developed to accurately predict gamuts and luminous fluxes.

Get full access to this article

View all access options for this article.

References

Sun

Wang

CH.

Specially designed driver circuits to stabilize LED light output without a photodetector. IEEE Transactions on Power Electronics 2011; 27: 4140–4152.

Wen

Zhou

Liu

, et al. Colour revolution: toward ultra-wide colour gamut displays. Journal of Physics D: Applied Physics 2021; 54: 1–19.

, et al. Full-colour realization of micro-LED displays. Nanomaterials 2020; 10: 2482.

Guo

Chen

, et al. The impact of luminous properties of red, green, and blue mini-LEDs on the colour gamut. IEEE Transactions on Electron Devices 2019; 66: 2263–2268.

Tong

Guo

Zhong

, et al. Effect of current on the inhomogeneous light emission from AlGaInP-based flip-chip red mini-LEDs. IEEE Electron Device Letters 2022; 43: 402–405.

Dang

Wang

Liu

, et al. Four-component, white LED with good colour quality and minimum damage to traditional Chinese paintings. Lighting Research and Technology 2019; 51: 1077–1091.

Tong

Yang

Zheng

, et al. Luminous characteristics of RGBW mini-LED integrated matrix devices for healthy displays. Optics and Laser Technology 2024; 170: 110229.

Zhang

Zhou

, et al. Research Note: LED chip-on-board packaging technology for strict colour tolerance. Lighting Research and Technology 2017; 49: 1052–1057.

Xie

Sun

Gong

, et al. Response nonuniformity modelling for colour imaging systems. Lighting Research and Technology 2023; 55: 204–217.

10.

Xue

Jin

, et al. Compromising circadian performance and colour gamut Rec. 2020 for achieving healthy LED displays. Optik 2023; 282: 170864.

11.

Liu

Jiang

Liu

, et al. RGBW LED mixing temperature compensation method with high output consistency. Optics and Laser Technology 2024; 170: 110440.

12.

Kalustova

Kornaga

Rybalochka

, et al. RGBW lighting systems: influence of the white LED. Semiconductor Physics, Quantum Electronics and Optoelectronics 2022; 25: 76–82.

13.

Eissfeldt

Khanh

TQ.

Algorithm for real-time colour mixing of a five-channel LED system while optimising spectral quality parameters. Lighting Research and Technology 2022; 54: 563–575.

14.

Padmasali

Kini

SG.

Experimental investigation and empirical modelling of thermal and drive current effect on optical performance of commercial LEDs. Lighting Research and Technology 2021; 53: 581–593.

15.

Liu

Chen

Zheng

, et al. Two-dimensional photothermal modeling of multichip LEDs device with thermal coupling matrix by microscopic hyperspectral imaging. IEEE Transactions on Electron Devices 2024; 71: 6198–6207.

16.

Shen

Chen

, et al. Measurement model of circadian action factor of phosphor-converted white LEDs based on photometric, electrical, and thermal properties. Metrologia 2024; 61: 025002.

17.

Tan

Yao

Wang

, et al. Characteristics of micro-size light-emitting diode with pentagon-type structure. IEEE Photonics Technology Letters 2021; 33: 1041–1135.

18.

Commission International de l’Éclairage. Colorimetry, 4th edition. CIE 015:2018. Vienna: CIE, 2018.

19.

American National Standard. Electric Lamps-Specifications for the Chromaticity of Solid State Lighting Products. ANSI C78.377. New York, NY: American National Standards Institute (ANSI), 2024.

20.

Keppens

Ryckaert

Deconinck

, et al. Modeling high power light-emitting diode spectra and their variation with junction temperature. Journal of Applied Physics 2010; 108: 043104.

21.

Vaskuri

Kärhä

Baumgartner

, et al. Relationships between junction temperature, electroluminescence spectrum and ageing of light-emitting diodes. Metrologia 2018; 55: S86.

22.

Kore

Durmus

Curve-fitting correction method for the nonlinear dimming response of tunable SSL devices. Technologies 2023; 11: 162.

23.

Hui

Qin

YX.

A general photo-electro-thermal theory for light-emitting-diode (LED) systems. IEEE Transactions on Power Electronics 2009; 24: 1967–1976.

24.

Hui

Chen

Tao

An extended photoelectrothermal theory for LED systems: a tutorial from device characteristic to system design for general lighting. IEEE Transactions on Power Electronics 2012; 27: 4571–4583.

25.

Storn

Price

Differential evolution – a simple and efficient heuristic for global optimization over continuous spaces. Journal of Global Optimization 1997; 11: 341–359.

26.

Commission International de l’Éclairage. Chromaticity Difference Specification for Light Sources. CIE TN 001: 2014. Vienna: CIE, 2014.

27.

Royer

M P.

Tutorial: Background and guidance for using the ANSI/IES TM-30 method for evaluating light source color rendition. Leukos 2022; 18: 191–231.

28.

Cree

LED

. Cree XLamp XM-L Color LEDs [Data sheet]. https://downloads.cree-led.com/files/ds/x/XLamp-XML-Color.pdf (2023, accessed 21 September 2025).

Electrothermal and optical impacts on two-dimensional colour gamut properties of red–green–blue LED devices

Abstract

Get full access to this article

References