mOptical Sensing for the Internet of Things: A Smartphone‐Controlled Platform for Temperature Monitoring

Ramalho, João F. C. B.; Carlos, Luís D.; André, Paulo S.; Ferreira, Rute A. S.

doi:10.1002/adpr.202000211

Cited by 33 publications

(33 citation statements)

References 111 publications

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“…Anti-counterfeiting systems that can rely solely on the use of smartphones as that hardware component in an authentication strategy are attractive and convenient as smartphones are ubiquitous 5 , 25 – 29 . However, such systems would need to meet several requirements to permit the reliance on only a smartphone being used and no additional hardware being required for the complete authentication process.…”

Section: Introductionmentioning

confidence: 99%

Dual-color dynamic anti-counterfeiting labels with persistent emission after visible excitation allowing smartphone authentication

Katumo

Richards

et al. 2022

Sci Rep

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A significant impediment to the deployment of anti-counterfeiting technologies is the reliance on specialized hardware. Here, anti-counterfeiting labels are developed that are both excited and detected using a smartphone. The persistent luminescence pattern and color changes on the timescale of hundreds of milliseconds to seconds. The labels can be authenticated by comparing still images from the red and green channels of video acquired at known times after flashlight excitation against expected reference patterns. The labels are based on a green-emitting SrAl2O4: Eu2+,Dy3+ (SAED), and red-emitting CaS:Eu2+ phosphors whose lifetimes are varied: (i) for SAED from 0.5 to 11.7 s by annealing the commercial material in air; and (ii) CaS:Eu2+ from 0.1 to 0.6 s by varying the dopant concentration. Examples of anti-counterfeiting labels exhibiting changing emission patterns and colors on a seven-segment display, barcode, and emoji are demonstrated. These results demonstrate that phosphors with visible absorption and tunable persistent luminescence lifetimes on the order of hundreds of milliseconds to seconds are attractive for anti-counterfeiting applications as they allow authentication to be performed using only a smartphone. Further development should allow richer color shifts and enhancement of security by embedding further covert anti-counterfeiting features.

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Section: Introductionmentioning

confidence: 99%

Dual-color dynamic anti-counterfeiting labels with persistent emission after visible excitation allowing smartphone authentication

Katumo

Richards

et al. 2022

Sci Rep

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“…The recent reports on mobile optical sensing mediated by smartphones appear as an intriguing strategy to enable large‐scale sensing and tracking mediated by the user. [ 10 ] Very few works address simultaneously sensing and tracking, [ 10–13 ] most of the reports focused only on temperature sensing, though photographic records from the luminescent materials recorded with a smartphone or a digital camera. [ 14–16 ] The thermometric parameter relies on the color variation arising from intensity variations.…”

Section: Introductionmentioning

confidence: 99%

“…From the practical temperature‐sensing point of view, luminescent quick response (QR) codes stand out as smart labels able to provide sensing and allowing the data to be sent over the IoT network, enabling the tracking functionality. [ 10 ] QR codes act as the gateway to IoT due to the growing use of smartphones/mobile devices and their properties such as fast and easy reading, capacity to store more information than that found in conventional codes, and versatility associated with the rapid and simplified access to information. [ 13,37 ] An intriguing example is the use of colored multiplexed luminescent QR codes based on organic−inorganic hybrids (e.g., diureasils [ 38 ] ) modified by trivalent lanthanide (Ln 3+ ) ions.…”

Section: Introductionmentioning

confidence: 99%

Customized Luminescent Multiplexed Quick‐Response Codes as Reliable Temperature Mobile Optical Sensors for eHealth and Internet of Things

Ramalho

Dias

et al. 2021

Advanced Photonics Research

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Internet of things (IoT) and health are two fields that have the potential to grow together. From their connection arises the concept of eHealth which refers essentially to the use of information and communication technologies in healthcare services. [1,2] This concept benefits from the advances of intelligent and integrated technological systems that are expected to live in and onto our bodies in different forms of flexible wearables. [3,4] Healthcare assisted by portable and wireless technologies is often termed mobile health (mHealth), [5,6] in which smartphones stand out as the most used ones. The combination of eHealth and mHealth enables monitoring and health tracking, providing vital information for remote medicine analysis (or in point of care) and successfully detecting health abnormalities. [7] Moreover, eHealth and mHealth can mitigate the lack of infrastructural or human resources in underprivileged regions. [1] Requisites for eHealth and mHealth medical devices are being designed for customized in-home care toward continuous and noninvasive monitoring. [8] Among the vital signals, body temperature stands out as the easiest and typically monitored one by common persons to infer the health condition. The pandemic scenario exacerbated such need for sense in real time through sustainable and multifunctional labels of body temperature and the fast tracking of people information (e.g., COVID-19 test results, places visited).The near-infrared (NIR) thermal cameras are one of the main devices used due to the fast response times and noninterference to electromagnetic fields in the working environment. Nonetheless, ambient conditions (e.g., stray light, reflected radiation, flame, or gas steam) may lead to temperature uncertainty of up to 1-8%. [9] In addition, the temperature readout requires human resources, being time-consuming and error prone, and people tracking is not possible to be done simultaneously. The recent reports on mobile optical sensing mediated by smartphones appear as an intriguing strategy to enable large-scale sensing and tracking mediated by the user. [10] Very few works address simultaneously sensing and tracking, [10][11][12][13] most of the reports focused only on temperature sensing, though photographic records from the luminescent materials recorded with a

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“…In addition, this approach paves the way for coupling the temperature sensing and colortuning properties to QR codes to develop optical sensors that can be read by smartphones, which is an exciting approach for mobile optical (mOptical) sensing. [35,36] Nevertheless, the use of such an advanced strategy for realworld applications only becomes attractive if one may circumvent dispendious fabrication routes of the QR codes, time-consuming data analysis, and complex implementation. In this way, we herein present a novel method to obtain smart tags by serigraph printing using a sustainable strategy to produce optically active inks using polystyrene (PS) recycled from expanded polystyrene (EPS) package wastes through its dissolution into d-limonene, a green solvent extract from orange peel.…”

Section: Introductionmentioning

confidence: 99%

Sustainable Smart Tags with Two‐Step Verification for Anticounterfeiting Triggered by the Photothermal Response of Upconverting Nanoparticles

Maturi

Brites

Silva

et al. 2021

Advanced Photonics Research

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Quick‐response (QR) codes are gaining much consideration in recent years due to their simple and fast readability compared with conventional barcodes. QR codes provide increased storage capacity and safer access to information, fostering the development of optical or printed smart tags as preferred tools for the Internet of Things (IoT). Herein, the combination of Yb3+/Er3+‐doped NaGdF4 upconverting nanoparticles (UCNPs) with recovered plastic for the fabrication of sustainable screen‐printed QR codes is reported. Their photothermal response under distinct power densities of the 980 nm laser irradiation (15–115 W cm−2) induces color‐tuning and temperature sensing. This power dependence is exploited to design a double key molecular keylock accessed by a smartphone camera through the red (R), green (G), and blue (B) (RGB) additive color model and upconversion thermometry. The latter is based on the integrated areas of the 2H11/2→4I15/2 and 4S3/2→4I15/2 Er3+ transitions using the interconnectivity and integration into the IoT network of the mobile phone to download the temperature calibration curve of the UCNPs from a remote server. These findings illustrate the potential of QR codes‐bearing UCNPs toward the design of smart tags for mobile optical sensing and anticounterfeiting.

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mOptical Sensing for the Internet of Things: A Smartphone‐Controlled Platform for Temperature Monitoring

Cited by 33 publications

References 111 publications

Dual-color dynamic anti-counterfeiting labels with persistent emission after visible excitation allowing smartphone authentication

Dual-color dynamic anti-counterfeiting labels with persistent emission after visible excitation allowing smartphone authentication

Customized Luminescent Multiplexed Quick‐Response Codes as Reliable Temperature Mobile Optical Sensors for eHealth and Internet of Things

Sustainable Smart Tags with Two‐Step Verification for Anticounterfeiting Triggered by the Photothermal Response of Upconverting Nanoparticles

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