research-article

Open access

AgriTera: Accurate Non-Invasive Fruit Ripeness Sensing via Sub-Terahertz Wireless Signals

Authors:

Sayed Saad Afzal,

Atsutse Kludze,

Subhajit Karmakar,

Ranveer Chandra,

Yasaman GhasempourAuthors Info & Claims

ACM MobiCom '23: Proceedings of the 29th Annual International Conference on Mobile Computing and Networking

Article No.: 61, Pages 1 - 15

https://doi.org/10.1145/3570361.3613275

Published: 02 October 2023 Publication History

Abstract

The ability to assess the quality of fruit and vegetables at scale can revolutionize the agriculture sector and significantly reduce food waste. In this paper, we present AgriTera, a novel solution for accurate non-invasive, and contract-free fruit ripeness sensing via sub-terahertz wireless signals. The key idea is that sugar and water concentrations in fruit (that are associated with fruit ripening) leave unique non-uniform footprints in the wide band spectrum of the reflected signal off of the fruits. AgriTera utilizes the sub-THz bands for its wide bandwidth, sensitivity to water, mm-scale penetration depth, and non-ionizing features that offer high-resolution inferences from the peel as well as the pulp underneath the peel. We develop a chemometric model that translates the reflection spectra to well-known ripeness metrics, namely Dry Matter and Brix. We conduct extensive over-the-air experiments with commercially available sub-THz transceivers. We compare our results with ground truth values captured by a specialized quality sensor and a vision-based scheme that infers ripeness based on changes in the appearance of the fruit. We demonstrate that AgriTera can accurately estimate Brix and Dry Matter in three different types of fruit with an average Normalized RMSE value of 0.55%, an error that yields a negligible impact on taste and is imperceivable by the consumer.

References

[1]

2014. Food Loss---Questions About the Amount and Causes Still Remain. https://www.ers.usda.gov/amber-waves/2014/june/food-loss-questions-about-the-amount-and-causes-still-remain/ Accessed: 2023-03-11.

[2]

2022. Food Waste Research. https://www.epa.gov/land-research/food-waste-research#why Accessed: 2023-03-11.

[3]

2023. Food Waste and Food Resue. https://www.feedingamerica.org/our-work/reduce-food-waste Accessed: 2023-03-11.

[4]

2023. How Many Fruits and Veggies do We Waste per Year? https://www.goruvi.com/blogs/news/644-million-tons-of-wasted-fruits-and-veggies-each-year Accessed: 2023-03-11.

[5]

Israel Arzate-Vázquez, José Jorge Chanona-Pérez, María de Jesús Perea-Flores, Georgina Calderón-Domínguez, Marco A Moreno-Armendáriz, Hiram Calvo, Salvador Godoy-Calderón, Roberto Quevedo, and Gustavo Gutiérrez-López. 2011. Image Processing Applied to Classification of Avocado Variety Hass (Persea americana Mill.) during the Ripening Process. Food and Bioprocess Technology 4 (2011), 1307--1313.

[6]

Richard D Averitt, Willie J Padilla, Hou-Tong Chen, John F O'Hara, Antoinette J Taylor, Clark Highstrete, Mark Lee, Joshua M.O. Zide, SR Bank, and Arthur C Gossard. 2007. Terahertz Metamaterial Devices. In Terahertz Physics, Devices, and Systems II, Vol. 6772. SPIE, 23--31.

[7]

Cornelius Barry and James Giovannoni. 1997. Ethylene and Fruit Ripening. Journal of Plant Growth Regulation 26 (01 1997).

[8]

Maxime Bernier, Frédéric Garet, and Jean-Louis Coutaz. 2017. Determining the Complex Refractive Index of Materials in the Far-Infrared from Terahertz Time-Domain Data. In Terahertz Spectroscopy, Jamal Uddin (Ed.). IntechOpen, Rijeka, Chapter 7.

[9]

Indu Chandrasekaran, Shubham Panigrahi, Lankapalli Ravikanth, and Chandra Singh. 2019. Potential of Near-Infrared (NIR) Spectroscopy and Hyperspectral Imaging for Quality and Safety Assessment of Fruits: an Overview. Food Analytical Methods 12 (11 2019).

[10]

Taiyun Chi, Min-Yu Huang, Sensen Li, and Hua Wang. 2017. 17.7 A Packaged 90-to-300GHz Transmitter and 115-to-325GHz Coherent Receiver in CMOS for Full-Band Continuous-wave mm-Wave Hyper-spectral Imaging. In Proc. of IEEE ISSCC.

[11]

Kim Seng Chia, Mohamad Nur Hakim Jam, Zeanne Gan, and Nurlaila Ismail. 2020. Pre-dispersive Near-infrared Light Sensing in Non-destructively Classifying the Brix of Intact Pineapples. Journal of Food Science and Technology 57 (2020), 4533--4540.

[12]

Bryan G. Coombe, Robert J. Dundon, and Andrew W. S. Short. 1980. Indices of Sugar---acidity as Ripeness Criteria for Winegrapes. Journal of the Science of Food and Agriculture 31, 5 (1980), 495--502.

[13]

Bruno G Defilippi, Troy Ejsmentewicz, María Paz Covarrubias, Orianne Gudenschwager, and Reinaldo Campos-Vargas. 2018. Changes in cell wall pectins and their relation to postharvest mesocarp softening of "Hass" avocados (Persea americana Mill.). Plant Physiology and Biochemistry 128 (2018), 142--151.

[14]

Manoj Dora, Joshua Wesana, Xavier Gellynck, Nitin Seth, Bidit Dey, and Hans De Steur. 2020. Importance of Sustainable Operations in Food Loss: Evidence from the Belgian Food Processing Industry. Annals of operations research 290 (2020), 47--72.

[15]

Birgit Esser, Jan M Schnorr, and Timothy M Swager. 2012. Selective detection of ethylene gas using carbon nanotube-based devices: utility in determination of fruit ripeness. Angewandte Chemie International Edition 51, 23 (2012), 5752--5756.

[16]

Felix. [n. d.]. F-750 Produce Quality Meter. https://felixinstruments.com/

[17]

Yasaman Ghasempour, Yasith Amarasinghe, Chia-Yi Yeh, Edward Knightly, and Daniel M Mittleman. 2021. Line-of-sight and non-line-of-sight links for dispersive terahertz wireless networks. APL Photonics 6, 4 (2021).

[18]

Yasaman Ghasempour, Rabi Shrestha, Aaron Charous, Edward Knightly, and Daniel M Mittleman. 2020. Single-shot link discovery for terahertz wireless networks. Nature communications 11, 1 (2020), 2017.

[19]

Yasaman Ghasempour, Chia-Yi Yeh, Rabi Shrestha, Yasith Amarasinghe, Daniel Mittleman, and Edward W Knightly. 2020. LeakyTrack: Noncoherent single-antenna nodal and environmental mobility tracking with a leaky-wave antenna. In SenSys' 20: Proceedings of the 18th Conference on Embedded Networked Sensor Systems.

Digital Library

[20]

Gregory Gougeon, Yoann Corre, and Mohammed Zahid Aslam. 2019. Ray-based Deterministic Channel Modelling for sub-THz Band. In 2019 IEEE 30th International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC Workshops). 1--6.

[21]

Aoife Gowen, Créidhe O'Sullivan, and Colm O'Donnell. 2012. Terahertz Time Domain Spectroscopy and Imaging: Emerging Techniques for Food Process Monitoring and Quality Control. Trends in Food Science & Technology 25, 1 (2012), 40--46.

[22]

Aoife Gowen, Créidhe O'Sullivan, and Colm O'Donnell. 2012. Terahertz time domain spectroscopy and imaging: Emerging Techniques for Food Process Monitoring and Quality Control. Trends in Food Science & Technology 25, 1 (2012), 40--46.

[23]

Mohammed Hassan and Chakravarthy Bhagvati. 2012. Structural Similarity Measure for Color Images. International Journal of Computer Applications 43, 14 (2012), 7--12.

[24]

Wen-Ding Huang, Sanchali Deb, Young-Sik Seo, Smitha Rao, Mu Chiao, and J. C. Chiao. 2012. A Passive Radio-Frequency pH-Sensing Tag for Wireless Food-Quality Monitoring. IEEE Sensors Journal 12, 3 (2012), 487--495.

[25]

Rovshen Ishangulyyev, Sanghyo Kim, and Sang Hyeon Lee. 2019. Understanding Food Loss and Waste --- Why are We Losing and Wasting Food? Foods 8, 8 (2019), 297.

[26]

Peter D Jamieson, John R Porter, and DR Wilson. 1991. A Test of the Computer Simulation Model ARCWHEAT1 on Wheat Crops Grown in New Zealand. Field crops research 27, 4 (1991), 337--350.

[27]

Steffen Janssen, Katrin Schmitt, Michael Blanke, Marie-Luise Bauersfeld, Jürgen Wöllenstein, and Walter Lang. 2014. Ethylene Detection in Fruit Supply Chains. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 372, 2017 (2014), 20130311.

[28]

Christian Jördens, Maik Scheller, Björn Breitenstein, Dirk Selmar, and Martin Koch. 2009. Evaluation of Leaf Water Status by Means of Permittivity at Terahertz Frequencies. Journal of biological physics 35 (2009), 255--264.

[29]

Toru Katsumata, Hiroaki Aizawa, Shuji Komuro, Shigeo Ito, and Takeshi Matsumoto. 2019. Non-destructive Evaluation of Orange Juice Based on Optical Scattering Intensities. Optik 182 (2019), 1064--1073.

[30]

Matthew D. Kleinhenz and Natalie R. Bumgarner. 2013. Using ° Brix as an Indicator of Vegetable Quality An Overview of the Practice.

[31]

Atsutse Kludze and Yasaman Ghasempour. 2023. {LeakyScatter}: A {Frequency-Agile} Directional Backscatter Network Above 100 {GHz}. In 20th USENIX Symposium on Networked Systems Design and Implementation (NSDI 23). 375--388.

[32]

Atsutse Kludze, Rabi Shrestha, Chowdhury Miftah, Edward Knightly, Daniel Mittleman, and Yasaman Ghasempour. 2022. Quasi-optical 3D localization using asymmetric signatures above 100 GHz. In Proceedings of the 28th Annual International Conference on Mobile Computing And Networking. 120--132.

Digital Library

[33]

Erika Kress-Rogers and Christopher JB Brimelow. 2001. Instrumentation and Sensors for the Food Industry. Vol. 65. Woodhead Publishing.

[34]

Shreya Lal, Santi Kumari Behera, Prabira Kumar Sethy, and Amiya Kumar Rath. 2017. Identification and Counting of Mature Apple Fruit Based on BP Feed Forward Neural Network. In 2017 Third International Conference on Sensing, Signal Processing and Security (ICSSS). IEEE, 361--368.

[35]

Yutong Liu, Landu Jiang, Linghe Kong, Qiao Xiang, Xue Liu, and Guihai Chen. 2022. Wi-Fruit: See Through Fruits with Smart Devices. 5, 4 (2022).

[36]

Luna. 2018. The TeraMetrix T-Ray® 5000 Series Intelligent Terahertz Control Unit. https://lunainc.com/blog/terametrix-t-rayr-5000-series-intelligent-terahertz-control-unit

[37]

W. B. McGlasson. 1985. Ethylene and Fruit Ripening. HortScience 20, 1 (1985), 51 -- 54.

[38]

Daniel M. Mittleman, Rune H. Jacobsen, and Martin C. Nuss. 1996. T-ray Imaging. IEEE Journal of Selected Topics in Quantum Electronics 2, 3 (1996), 679--692.

[39]

Vahid Mohammadi, Kamran Kheiralipour, and Mahdi Ghasemi-Varnamkhasti. 2015. Detecting Maturity of Persimmon Fruit Based on Image Processing Technique. Scientia Horticulturae 184 (2015), 123--128.

[40]

Siddhanth (Sid) Mookerjee, Yann Cornil, and JoAndrea Hoegg. 2021. From Waste to Taste: How "Ugly" Labels Can Increase Purchase of Unattractive Produce. Journal of Marketing 85, 3 (2021), 62--77.

[41]

Leandro Oliveira and Adriana Franca. 2011. Applications of Near Infrared Spectroscopy (NIRS) in Food Quality Evaluation. Food Quality: Control, Analysis and Consumer Concerns (02 2011), 131--180.

[42]

Daniel I. Onwude, Guangnan Chen, Nnanna Eke-emezie, Abraham Kabutey, Alfadhl Yahya Khaled, and Barbara Sturm. 2020. Recent Advances in Reducing Food Losses in the Supply Chain of Fresh Agricultural Produce. Processes 8, 11 (2020).

[43]

John Palmer, F. Harker, D Tustin, and Jason Johnston. 2010. Fruit Dry Matter Concentration: A New Quality Metric for Apples. Journal of the science of food and agriculture 90 (12 2010), 2586--94.

[44]

Vijay Paul, Rakesh Pandey, and Girish C Srivastava. 2012. The Fading Distinctions between Classical Patterns of Ripening in Climacteric and Non-climacteric Fruit and the Ubiquity of Ethylene --- An Overview. Journal of food science and technology 49 (2012), 1--21.

[45]

Sastia Prama Putri, Muhammad Maulana Malikul Ikram, Arisa Sato, Hadi Akbar Dahlan, Della Rahmawati, Yukina Ohto, and Eiichiro Fukusaki. 2022. Application of Gas Chromatography-mass Spectrometry-based Metabolomics in Food Science and Technology. Journal of Bioscience and Bioengineering (2022).

[46]

Hamed Rahmani, Darshan Shetty, Mahmoud Wagih, Yasaman Ghasempour, Valentina Palazzi, Nuno B Carvalho, Ricardo Correia, Alessandra Costanzo, Dieff Vital, Federico Alimenti, et al. 2023. Next-generation IoT devices: Sustainable eco-friendly manufacturing, energy harvesting, and wireless connectivity. IEEE Journal of Microwaves 3, 1 (2023), 237--255.

[47]

Robin Raju, Greg E. Bridges, and Sharmistha Bhadra. 2020. Wireless Passive Sensors for Food Quality Monitoring: Improving the Safety of Food Products. IEEE Antennas and Propagation Magazine 62, 5 (2020), 76--89.

[48]

Aifeng Ren, Adnan Zahid, Xiaodong Yang, Akram Alomainy, Muhammad Imran, and Qammer Abbasi. 2019. Terahertz (THz) Application in Food Contamination Detection. (12 2019).

[49]

Aifeng Ren, Adnan Zahid, Ahmed Zoha, Syed Aziz Shah, Muhammad Ali Imran, Akram Alomainy, and Qammer H Abbasi. 2019. Machine learning driven approach towards the quality assessment of fresh fruits using non-invasive sensing. IEEE Sensors Journal 20, 4 (2019), 2075--2083.

[50]

Yili Ren, Sheng Tan, Linghan Zhang, Zi Wang, Zhi Wang, and Jie Yang. 2020. Liquid Level Sensing Using Commodity WiFi in a Smart Home Environment. Proc. ACM Interact. Mob. Wearable Ubiquitous Technol. 4, 1, Article 24 (mar 2020), 30 pages.

Digital Library

[51]

Patrick Reynaert, Wouter Steyaert, Alexander Standaert, Dragan Simic, and Guo Kaizhe. 2017. mm-Wave and THz Circuit Design in Standard CMOS Technologies: Challenges and Opportunities. In 2017 IEEE Asia Pacific Microwave Conference (APMC). IEEE, 85--88.

[52]

Carlos Eduardo Rodríguez-López, Carmen Hernández-Brenes, Víctor Treviño, and Rocío I Díaz de la Garza. 2017. Avocado Fruit Maturation and Ripening: Dynamics of Aliphatic Acetogenins and Lipidomic Profiles from Mesocarp, Idioblasts and Seed. BMC plant biology 17, 1 (2017), 1--23.

[53]

James Rogers. 2021. See Beyond the Peel. https://www.apeel.com/blog/see-beyond-the-peel

[54]

Kaushik Sengupta and Ali Hajimiri. 2012. A0.28 THz Power-Generation and Beam-Steering Array in CMOS based on Distributed Active Radiators. IEEE Journal of Solid-State Circuits 47, 12 (2012), 3013--3031.

[55]

Ruiyi Shen and Yasaman Ghasempour. 2023. Rough Surfaces Scattering and Mobility-Resilient Terahertz Wireless Links. In 2023 48th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz). 1--2.

[56]

KP Sudheer and V Indira. 2007. Post Harvest Technology of Horticultural Crops. Vol. 7. New India Publishing.

[57]

Xudong Sun, Jiajun Li, Yun Shen, and Wenping Li. 2021. Nondestructive Detection of Insect Foreign Bodies in Finishing Tea Product Based on Terahertz Spectrum and Image. Frontiers in Nutrition 8 (2021), 757491.

[58]

Ee Lim Tan, Wen Ni Ng, Ranyuan Shao, Brandon D Pereles, and Keat Ghee Ong. 2007. A Wireless, Passive Sensor for Quantifying Packaged Food Quality. Sensors 7, 9 (2007), 1747--1756.

[59]

Sheng Tan, Linghan Zhang, and Jie Yang. 2018. Sensing Fruit Ripeness Using Wireless Signals. In 2018 27th International Conference on Computer Communication and Networks (ICCCN). 1--9.

[60]

Rucha Thakur, Gaurav Suryawanshi, Hardik Patel, and Janhavi Sangoi. 2020. An Innovative Approach For Fruit Ripeness Classification. In 2020 4th International Conference on Intelligent Computing and Control Systems (ICICCS). 550--554.

[61]

Zhicheng Yang, Parth H Pathak, Mo Sha, Tingting Zhu, Junai Gan, Pengfei Hu, and Prasant Mohapatra. 2019. On the Feasibility of Estimating Soluble Sugar Content using Millimeter-wave. In Proceedings of the International Conference on Internet of Things Design and Implementation. 13--24.

Digital Library

[62]

Borwen You, Ching-Yu Chen, Chin-Ping Yu, Pei-Hwa Wang, and Ja-Yu Lu. 2018. Frequency-Dependent Skin Penetration Depth of Terahertz Radiation Determined by Water Sorption-desorption. Opt. Express 26, 18 (Sep 2018), 22709--22721.

[63]

Guozhong Zhao, Maarten Ter Mors, Tom Wenckebach, and Paul CM Planken. 2002. Terahertz Dielectric Properties of Polystyrene Foam. JOSA B 19, 6 (2002), 1476--1479.

Cited By

Zhang ZSong DZhou AMa H(2024)airTac: A Contactless Digital Tactile Receptor for Detecting Material and Roughness via Terahertz SensingProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36785868:3(1-37)Online publication date: 9-Sep-2024
https://dl.acm.org/doi/10.1145/3678586
Chang ZZhang FXiong JChen WZhang DGanesan DLane NShi W(2024)MSense: Boosting Wireless Sensing Capability Under Motion InterferenceProceedings of the 30th Annual International Conference on Mobile Computing and Networking10.1145/3636534.3649350(108-123)Online publication date: 29-May-2024
https://dl.acm.org/doi/10.1145/3636534.3649350
Thaddeus LReddy CBhadauria YShah DGulati MVarshney A(2024)TunnelSense: Low-Power, Non-Contact Sensing Using Tunnel Diodes2024 IEEE International Conference on RFID (RFID)10.1109/RFID62091.2024.10582671(154-159)Online publication date: 4-Jun-2024
https://doi.org/10.1109/RFID62091.2024.10582671

Index Terms

AgriTera: Accurate Non-Invasive Fruit Ripeness Sensing via Sub-Terahertz Wireless Signals

Index terms have been assigned to the content through auto-classification.

Recommendations

AgriTera: Accurate Non-Invasive Fruit Ripeness Sensing via Sub-Terahertz Wireless Signals

The potential to transform the agriculture sector and reduce food waste significantly lies in the ability to assess the quality of fruits and vegetables on a large scale. This article introduces AgriTera, an innovative solution that utilizes sub-...
Meta-Sticker: Sub-Terahertz Metamaterial Stickers for Non-Invasive Mobile Food Sensing
SenSys '23: Proceedings of the 21st ACM Conference on Embedded Networked Sensor Systems

Food waste is one of the greatest economic and ethical challenges in the world. Empowering consumers with the ability to assess the quality of fruit can be a game changer for reducing waste and motivating a healthier diet. In this paper, we present Meta-...
Mapping sub-pixel occurrence of an alien invasive Hyptis suaveolens L. Poit. using spectral unmixing technique

<italic>Hyptis suaveolens</italic> L. Poit. is an alien invasive plant species in the Indian subcontinent introduced from tropical America, and is an emerging invader of the Himalayan foothills. This study discusses the application of spectral unmixing ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Conferences

ACM MobiCom '23: Proceedings of the 29th Annual International Conference on Mobile Computing and Networking

October 2023

1605 pages

ISBN:9781450399906

DOI:10.1145/3570361

Chairs:
Xavier Costa,
Joerg Widmer,
Co-chairs:
Diego Perino,
Domenico Giustiniano,
Program Chair:
Haitham Al Hassanieh,
Program Co-chairs:
Arash Asadi,
Landon Cox

Copyright © 2023 Owner/Author(s).

This work is licensed under a Creative Commons Attribution International 4.0 License.

Sponsors

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

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 02 October 2023

Check for updates

Author Tags

Qualifiers

Research-article

Funding Sources

Conference

ACM MobiCom '23

Sponsor:

SIGMOBILE

ACM MobiCom '23: 29th Annual International Conference on Mobile Computing and Networking

October 2 - 6, 2023

Madrid, Spain

Acceptance Rates

Overall Acceptance Rate 440 of 2,972 submissions, 15%

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

3
Total Citations
View Citations
3,609
Total Downloads

Downloads (Last 12 months)3,609
Downloads (Last 6 weeks)352

Reflects downloads up to 02 Oct 2024

Other Metrics

View Author Metrics

Citations

Cited By

Zhang ZSong DZhou AMa H(2024)airTac: A Contactless Digital Tactile Receptor for Detecting Material and Roughness via Terahertz SensingProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36785868:3(1-37)Online publication date: 9-Sep-2024
https://dl.acm.org/doi/10.1145/3678586
Chang ZZhang FXiong JChen WZhang DGanesan DLane NShi W(2024)MSense: Boosting Wireless Sensing Capability Under Motion InterferenceProceedings of the 30th Annual International Conference on Mobile Computing and Networking10.1145/3636534.3649350(108-123)Online publication date: 29-May-2024
https://dl.acm.org/doi/10.1145/3636534.3649350
Thaddeus LReddy CBhadauria YShah DGulati MVarshney A(2024)TunnelSense: Low-Power, Non-Contact Sensing Using Tunnel Diodes2024 IEEE International Conference on RFID (RFID)10.1109/RFID62091.2024.10582671(154-159)Online publication date: 4-Jun-2024
https://doi.org/10.1109/RFID62091.2024.10582671

View Options

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Get Access

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Publication

Media

Figures

Other

Tables

View Table of Contents