research-article

Open access

Liquid Testing with Your Smartphone

Authors:

Dina KatabiAuthors Info & Claims

MobiSys '19: Proceedings of the 17th Annual International Conference on Mobile Systems, Applications, and Services

Pages 275 - 286

https://doi.org/10.1145/3307334.3326078

Published: 12 June 2019 Publication History

Abstract

Surface tension is an important property of liquids. It has diverse uses such as testing water contamination, measuring alcohol concentration in drinks, and identifying the presence of protein in urine to detect the onset of kidney failure. Today, measurements of surface tension are done in a lab environment using costly instruments, making it hard to leverage this property in ubiquitous applications. In contrast, we show how to measure surface tension using only a smartphone. We introduce a new algorithm that uses the small waves on the liquid surface as a series of lenses that focus light and generate a characteristic pattern. We then use the phone camera to capture this pattern and measure the surface tension. Our approach is simple, accurate and available to anyone with a smartphone. Empirical evaluations show that our mobile app can detect water contamination and measure alcohol concentration. Furthermore, it can track protein concentration in the urine, providing an initial at-home test for proteinuria, a dangerous complication that can lead to kidney failure.

References

[1]

Apple. 2018. Accelerate Framework. https://developer.apple.com/documentation/accelerate .

[2]

RA Awad, ZMR Hassan, and Wafaa M Salama. 2014. Surface Tension and Foaming Properties as a Simple Index in Relation to Buffalo Milk Adulteration. International Journal of Dairy Science, Vol. 9 (2014), 106--115.

[3]

Tarun Kr Barik, Partha Roy Chaudhuri, Anushree Roy, and Sayan Kar. 2006. Probing liquid surface waves, liquid properties and liquid films with light diffraction. Measurement Science and Technology, Vol. 17, 6 (2006), 1553.

[4]

F Behroozi and A Perkins. 2006. Direct measurement of the dispersion relation of capillary waves by laser interferometry. American journal of physics, Vol. 74, 11 (2006), 957--961.

[5]

Joseph D Berry, Michael J Neeson, Raymond R Dagastine, Derek YC Chan, and Rico F Tabor. 2015. Measurement of surface and interfacial tension using pendant drop tensiometry. Journal of colloid and interface science, Vol. 454 (2015), 226--237.

[6]

Roger D Blandford and Kip S Thorne. 2008. Applications of classical physics .California Institute of Technology.

[7]

Edward Bormashenko and Albina Musin. 2009. Revealing of water surface pollution with liquid marbles. Applied Surface Science, Vol. 255, 12 (2009), 6429--6431.

[8]

H Chen, Jesus L Muros-Cobos, and A Amirfazli. 2018. Contact angle measurement with a smartphone. Review of Scientific Instruments, Vol. 89, 3 (2018), 035117.

[9]

H Chen, Jesus L Muros-Cobos, Juan A Holgado-Terriza, and A Amirfazli. 2017. Surface tension measurement with a smartphone using a pendant drop. Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 533 (2017), 213--217.

[10]

Marcelo Cicconet, Vighnesh Birodkar, Mads Lund, Michael Werman, and Davi Geiger. 2017. A convolutional approach to reflection symmetry. Pattern Recognition Letters, Vol. 95 (2017), 44--50.

[11]

Ashutosh Dhekne, Mahanth Gowda, Yixuan Zhao, Haitham Hassanieh, and Romit Roy Choudhury. 2018. LiquID: A Wireless Liquid IDentifier.

[12]

Charles J Diskin, Thomas J Stokes, Linda M Dansby, Thomas B Carter, and Lautrec Radcliff. 2000. Surface tension, proteinuria, and the urine bubbles of Hippocrates. The Lancet, Vol. 355, 9207 (2000), 901--902.

[13]

J Drelich, Ch Fang, and CL White. 2002. Measurement of interfacial tension in fluid-fluid systems. Encyclopedia of surface and colloid science, Vol. 3 (2002), 3158--3163.

[14]

P Lecomte Du Noüy. 1919. A new apparatus for measuring surface tension. The Journal of general physiology, Vol. 1, 5 (1919), 521.

[15]

FDS. 2018. Digital Tensiometer -- DCAT11. http://www.fdsc.com/wpdev15/"portfolio=dca11 .

[16]

Australian Government. 2018. Microalbumin Level. https://meteor.aihw.gov.au/content/index.phtml/itemId/270339/.

[17]

Nicolas-Alexandre Goy, Zakari Denis, Maxime Lavaud, Adrian Grolleau, Nicolas Dufour, Antoine Deblais, and Ulysse Delabre. 2017. Surface tension measurements with a smartphone. The Physics Teacher, Vol. 55, 8 (2017), 498--499.

[18]

Unsoo Ha, Yunfei Ma, Zexuan Zhong, Tzu-Ming Hsu, and Fadel Adib. 2018. Learning Food Quality and Safety from Wireless Stickers. In Proceedings of the 17th ACM Workshop on Hot Topics in Networks. ACM, 106--112.

Digital Library

[19]

FK Hansen and G Rødsrud. 1991. Surface tension by pendant drop: I. A fast standard instrument using computer image analysis. Journal of colloid and interface science, Vol. 141, 1 (1991), 1--9.

[20]

Kyu Keun Kang, Jung Ran Choi, Ji Young Song, Sung Wan Han, So Hyun Park, Woong Sun Yoo, Hwe Won Kim, Dongyoung Lee, Kyoung Hyoub Moon, Myung Hee Lee, et almbox. 2012. Clinical significance of subjective foamy urine. Chonnam medical journal, Vol. 48, 3 (2012), 164--168.

[21]

Kruss. 2018. Force Tensiometer -- K6. https://www.kruss-scientific.com/products/tensiometers/force-tensiometer-k6/.

[22]

Chia-Kai Liang, Li-Wen Chang, and Homer H Chen. 2008. Analysis and compensation of rolling shutter effect. IEEE Transactions on Image Processing (2008).

Digital Library

[23]

CE Mogensen. 1984. Microalbuminuria predicts clinical proteinuria and early mortality in maturity-onset diabetes. New England journal of medicine, Vol. 310, 6 (1984), 356--360.

[24]

D Nikolić and Lj Nevs ić. 2012. Determination of surface tension coefficient of liquids by diffraction of light on capillary waves. European Journal of Physics, Vol. 33, 6 (2012), 1677.

[25]

Richard J Potton. 2004. Reciprocity in optics. Reports on Progress in Physics, Vol. 67, 5 (2004), 717.

[26]

Veronica I Pye and Ruth Patrick. 1983. Ground water contamination in the United States. Science, Vol. 221, 4612 (1983), 713--718.

[27]

Tauhidur Rahman, Alexander T Adams, Perry Schein, Aadhar Jain, David Erickson, and Tanzeem Choudhury. 2016. Nutrilyzer: A Mobile System for Characterizing Liquid Food with Photoacoustic Effect. In SenSys. ACM.

Digital Library

[28]

Zhang Shi, Yi Zhang, Mingchao Liu, Dorian AH Hanaor, and Yixiang Gan. 2018. Dynamic contact angle hysteresis in liquid bridges. Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 555 (2018), 365--371.

[29]

James G Speight et almbox. 2005. Lange's handbook of chemistry . Vol. 1. McGraw-Hill New York.

[30]

MKC Sridhar and C Rami Reddy. 1984. Surface tension of polluted waters and treated wastewater. Environmental Pollution Series B, Chemical and Physical, Vol. 7, 1 (1984), 49--69.

[31]

F Tamm, G Sauer, M Scampicchio, and S Drusch. 2012. Pendant drop tensiometry for the evaluation of the foaming properties of milk-derived proteins. Food Hydrocolloids, Vol. 27, 2 (2012), 371--377.

[32]

Jackson Tan. {n. d.}. Correlation of Urinary Foam with Proteinuria in Patients with Chronic Kidney Disease. ({n. d.}).

[33]

Gonzalo Vazquez, Estrella Alvarez, and Jose M Navaza. 1995. Surface tension of alcohol

[34]

water from 20 to 50$^circC$. Journal of chemical and engineering data, Vol. 40, 3 (1995), 611--614.

[35]

GC Viberti, RJ Jarrett, U Mahmud, RD Hill, A Argyropoulos, and H Keen. 1982. Microalbuminuria as a predictor of clinical nephropathy in insulin-dependent diabetes mellitus. The Lancet, Vol. 319, 8287 (1982), 1430--1432.

[36]

Ju Wang, Jie Xiong, Xiaojiang Chen, Hongbo Jiang, Rajesh Krishna Balan, and Dingyi Fang. 2017. TagScan: Simultaneous target imaging and material identification with commodity RFID devices. In Proceedings of the 23rd Annual International Conference on Mobile Computing and Networking. ACM.

Digital Library

[37]

Mengxi Wei, Shuo Huang, Jing Wang, Haihong Li, Hujiang Yang, and Shihong Wang. 2015. The study of liquid surface waves with a smartphone camera and an image recognition algorithm. European Journal of Physics, Vol. 36, 6 (2015), 065026.

[38]

CH Whitnah. 1959. The surface tension of milk. A review1, 2. Journal of Dairy Science, Vol. 42, 9 (1959), 1437--1449.

[39]

Wikipedia. 2018a. Albumin. https://en.wikipedia.org/wiki/Albumin .

[40]

Wikipedia. 2018b. Surface Tension .

[41]

Wikipedia. 2018c. Tensiometer (surface tension) .

[42]

Hui-Shyong Yeo, Gergely Flamich, Patrick Schrempf, David Harris-Birtill, and Aaron Quigley. 2016. Radarcat: Radar categorization for input & interaction. In Proceedings of the 29th Annual Symposium on User Interface Software and Technology. ACM.

Digital Library

[43]

Yuehua Yuan and T Randall Lee. 2013. Contact angle and wetting properties. In Surface science techniques . Springer, 3--34.

[44]

Feng Zhu, Runcai Miao, Chunlong Xu, and Zanzan Cao. 2007. Measurement of the dispersion relation of capillary waves by laser diffraction. American Journal of Physics, Vol. 75, 10 (2007), 896--898.

Cited By

Niaz FZhang JZheng YKhalid MNiaz A(2024)mm-CUR: A Novel Ubiquitous, Contact-free, and Location-aware Counterfeit Currency Detection in Bundles Using Millimeter-Wave SensorACM Transactions on Sensor Networks10.1145/369497020:6(1-26)Online publication date: 5-Sep-2024
https://dl.acm.org/doi/10.1145/3694970
Chen MChen HNiu SShu YLiu JTan RHe YChen J(2024)UrineSpec: A Lightweight Near-Infrared Spectroscopy System for Metabolite Detection in UrineProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699375(799-810)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699375
Li ZLuo WZhang YChen JShu YZhang YShu YLiu JTan RHe YChen J(2024)ASLiquid: Non-Intrusive Liquid Counterfeit Identification with Your EarphonesProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699321(41-53)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699321
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Index Terms

Liquid Testing with Your Smartphone
1. Applied computing
  1. Physical sciences and engineering
    1. Physics
2. Human-centered computing
  1. Ubiquitous and mobile computing

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Published In

cover image ACM Conferences

MobiSys '19: Proceedings of the 17th Annual International Conference on Mobile Systems, Applications, and Services

June 2019

736 pages

ISBN:9781450366618

DOI:10.1145/3307334

General Chairs:
Junehwa Song
KAIST, South Korea
,
Minkyong Kim
Samsung Electronics
,
Program Chairs:
Nicholas D. Lane
University of Oxford & Samsung AI
,
Rajesh K. Balan
Singapore Management University

Copyright © 2019 ACM.

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SIGMOBILE: ACM Special Interest Group on Mobility of Systems, Users, Data and Computing

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New York, NY, United States

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Published: 12 June 2019

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MobiSys '19

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SIGMOBILE

MobiSys '19: The 17th Annual International Conference on Mobile Systems, Applications, and Services

June 17 - 21, 2019

Seoul, Republic of Korea

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Overall Acceptance Rate 274 of 1,679 submissions, 16%

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Cited By

Niaz FZhang JZheng YKhalid MNiaz A(2024)mm-CUR: A Novel Ubiquitous, Contact-free, and Location-aware Counterfeit Currency Detection in Bundles Using Millimeter-Wave SensorACM Transactions on Sensor Networks10.1145/369497020:6(1-26)Online publication date: 5-Sep-2024
https://dl.acm.org/doi/10.1145/3694970
Chen MChen HNiu SShu YLiu JTan RHe YChen J(2024)UrineSpec: A Lightweight Near-Infrared Spectroscopy System for Metabolite Detection in UrineProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699375(799-810)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699375
Li ZLuo WZhang YChen JShu YZhang YShu YLiu JTan RHe YChen J(2024)ASLiquid: Non-Intrusive Liquid Counterfeit Identification with Your EarphonesProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699321(41-53)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699321
Waghmare AChatterjee IIyer VPatel S(2024)WatchLink: Enhancing Smartwatches with Sensor Add-Ons via ECG InterfaceProceedings of the 37th Annual ACM Symposium on User Interface Software and Technology10.1145/3654777.3676329(1-13)Online publication date: 13-Oct-2024
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Yun JLee KLee KSun BJeon JKo JHwang IHan JOkoshi TKo JLiKamWa R(2024)PowDew: Detecting Counterfeit Powdered Food Products using a Commodity SmartphoneProceedings of the 22nd Annual International Conference on Mobile Systems, Applications and Services10.1145/3643832.3661877(210-222)Online publication date: 3-Jun-2024
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Shang FYang PYan DZhang SLi X(2024)LiquImagerProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36435098:1(1-29)Online publication date: 6-Mar-2024
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Chang LYang XLiu RXie GWang FWang J(2024)FSS-TagProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36314577:4(1-24)Online publication date: 12-Jan-2024
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Wang ZGuo YRen ZSong WSun ZChen CGuo BYu Z(2024)LiqDetectorProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36314437:4(1-24)Online publication date: 12-Jan-2024
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Liang YShi PZheng ZPu LZhou AMa H(2024)Mmtaster: A Mobile System for Fine-Grained and Robust Alcohol SensingIEEE Transactions on Mobile Computing10.1109/TMC.2023.333914123:7(7830-7847)Online publication date: Jul-2024
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Shang FYang PYan YLi X(2024)Contactless and fine-grained liquid identification utilizing sub-6GHz signalsIEEE Transactions on Mobile Computing10.1109/TMC.2023.3300356(1-16)Online publication date: 2024
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