Chinese Journal on Internet of Things
WU Jing, LI Sheng, ZHANG Jing, XIN Ming, TAO Ruowen, ZHOU Zhou, PAN Lijia, SHI Yi
WU Jing, LI Sheng, ZHANG Jing, XIN Ming, TAO Ruowen, ZHOU Zhou, PAN Lijia, SHI Yi. New flexible sensor based on the internet of things[J]. Chinese Journal on Internet of Things, doi: 10.11959/j.issn.2096—3750.2022.00294.
Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks
URL: https://www.infocomm-journal.com/wlw/EN/10.11959/j.issn.2096—3750.2022.00294
[1] JUNG M, KIM K, KIM B, et al. Paper-based bimodal sensor for electronic skin applications[J]. ACS Applied Materials & Interfaces, 2017, 9(32): 26974-26982. [2] WANG C Y, XIA K L, ZHANG M C, et al. An all-silk-derived dual-mode E-skin for simultaneous temperature-pressure detection[J]. ACS Applied Materials & Interfaces, 2017, 9(45): 39484-39492. [3] ZHAO S, ZHU R. Flexible bimodal sensor for simultaneous and independent perceiving of pressure and temperature stimuli[J]. Advanced Materials Technologies, 2017, 2(11): 1700183. [4] LIMAN M L R, ISLAM M T, HOSSAIN M M. Mapping the Progress in Flexible Electrodes for Wearable Electronic Textiles: Materials, Durability, and Applications[J]. Advanced Electronic Materials, 2022, 8(1). [5] KRISHNAMURTHI R, KUMAR A, GOPINATHAN D, et al. An Overview of IoT Sensor Data Processing, Fusion, and Analysis Techniques[J]. Sensors, 2020, 20(21). [6] MCEVOY M A, CORRELL N. Materials science. Materials that couple sensing, actuation, computation, and communication[J]. Science, 2015, 347(6228): 1261689. [7] ZHU C S, LEUNG V C M, SHU L, et al. Green Internet of Things for smart world[J]. IEEE Access, 3: 2151-2162. [8] ALSHEHRI F, MUHAMMAD G. A comprehensive survey of the Internet of Things (IoT) and AI-based smart healthcare[J]. IEEE Access, 9: 3660-3678. [9] RISTESKA STOJKOSKA B L, TRIVODALIEV K V. A review of Internet of Things for smart home: challenges and solutions[J]. Journal of Cleaner Production, 2017, 140: 1454-1464. [10] WANG A H, WANG P S, MIAO X Q, et al. A review on non-terrestrial wireless technologies for Smart City Internet of Things[J]. International Journal of Distributed Sensor Networks, 2020, 16(6): 155014772093682. [11] KIM K B, JANG W, CHO J Y, et al. Transparent and flexible piezoelectric sensor for detecting human movement with a boron nitride nanosheet (BNNS)[J]. Nano Energy, 2018, 54: 91-98. [12] JUNG W S, LEE M J, KANG M Y, et al. Powerful curved piezoelectric generator for wearable applications[J]. Nano Energy, 2015, 13: 174-181. [13] 姚宽明, 姚靖仪, 海照, 等. 用于触觉感知的自供能可拉伸压电橡胶皮肤电子器件[J]. 物理学报, 2020, 69(17): 178701. YAO K M, YAO J Y, HAI Z, et al. Stretchable self-powered epidermal electronics from piezoelectric rubber for tactile sensing[J]. Acta Physica Sinica, 2020, 69(17): 178701. [14] ZHANG D Z, WANG D Y, XU Z Y, et al. Diversiform sensors and sensing systems driven by triboelectric and piezoelectric nanogenerators[J]. Coordination Chemistry Reviews, 2021, 427: 213597. [15] KIM S L, CHOI K, TAZEBAY A, et al. Flexible power fabrics made of carbon nanotubes for harvesting thermoelectricity[J]. ACS Nano, 2014, 8(3): 2377-2386. [16] LV H C, LIANG L R, ZHANG Y C, et al. A flexible spring-shaped architecture with optimized thermal design for wearable thermoelectric energy harvesting[J]. Nano Energy, 2021, 88: 106260. [17] 柳冈, 王铁. 基于热电材料的新型传感器研究进展[J]. 化学学报, 2017, 75(11): 1029-1035. LIU G, WANG T. Research progress in thermoelectric materials for sensor application[J]. Acta Chimica Sinica, 2017, 75(11): 1029-1035. [18] PARK S, HEO S W, LEE W, et al. Self-powered ultra-flexible electronics via nano-grating-patterned organic photovoltaics[J]. Nature, 2018, 561(7724): 516-521. [19] THOSTENSON J O, LI Z, KIM C H J, et al. Integrated flexible conversion circuit between a flexible photovoltaic and supercapacitors for powering wearable sensors[J]. Journal of the Electrochemical Society, 2018, 165(8): B3122-B3129. [20] LIU X L, ZHAO Y, WANG W J, et al. Photovoltaic self-powered gas sensing: a review[J]. IEEE Sensors Journal, 2021, 21(5): 5628-5644. [21] KHAN Y, OSTFELD A E, LOCHNER C M, et al. Monitoring of vital signs with flexible and wearable medical devices[J]. Advanced Materials (Deerfield Beach, Fla), 2016, 28(22): 4373-4395. [22] WANG L R, XU T L, ZHANG X J. Multifunctional conductive hydrogel-based flexible wearable sensors[J]. TrAC Trends in Analytical Chemistry, 2021, 134: 116130. [23] HAN S T, PENG H Y, SUN Q J, et al. An overview of the development of flexible sensors[J]. Advanced Materials, 2017, 29(33): 1700375. [24] LI S, MA Z, CAO Z L, et al. Advanced wearable microfluidic sensors for healthcare monitoring[J]. Small, 2020, 16(9): 1903822. [25] SEGEV-BAR M, HAICK H. Flexible sensors based on nanoparticles[J]. ACS Nano, 2013, 7(10): 8366-8378. [26] 赵帅, 朱荣. 多感知集成的柔性电子皮肤[J]. 化学学报, 2019, 77(12): 1250-1262. ZHAO S, ZHU R. Flexible electronic skin with multisensory integration[J]. Acta Chimica Sinica, 2019, 77(12): 1250-1262. [27] TIEN N T, JEON S, KIM D I, et al. A flexible bimodal sensor array for simultaneous sensing of pressure and temperature[J]. Advanced Materials, 2014, 26(5): 796-804. [28] ZHANG F J, ZANG Y P, HUANG D Z, et al. Flexible and self-powered temperature–pressure dual-parameter sensors using microstructure-frame-supported organic thermoelectric materials[J]. Nature Communications, 2015, 6: 8356. [29] NAKATA S, ARIE T, AKITA S, et al. Wearable, flexible, and multifunctional healthcare device with an ISFET chemical sensor for simultaneous sweat pH and skin temperature monitoring[J]. ACS Sensors, 2017, 2(3): 443-448. [30] HUA Q L, SUN J L, LIU H T, et al. Skin-inspired highly stretchable and conformable matrix networks for multifunctional sensing[J]. Nature Communications, 2018, 9: 244. [31] GAO W, EMAMINEJAD S, NYEIN H Y Y, et al. Fully integrated wearable sensor arrays for multiplexed in situ perspiration analysis[J]. Nature, 2016, 529(7587): 509-514. [32] LEE S, FRANKLIN S, HASSANI F A, et al. Nanomesh pressure sensor for monitoring finger manipulation without sensory interference[J]. Science, 2020, 370(6519): 966-970. [33] WIOREK A, PARRILLA M, CUARTERO M, et al. Epidermal patch with glucose biosensor: pH and temperature correction toward more accurate sweat analysis during sport practice[J]. Analytical Chemistry, 2020, 92(14): 10153-10161. [34] ZHAO S, ZHU R. Electronic skin with multifunction sensors based on thermosensation[J]. Advanced Materials, 2017, 29(15): 1606151. [35] JIAN M Q, XIA K L, WANG Q, et al. Flexible and highly sensitive pressure sensors based on bionic hierarchical structures[J]. Advanced Functional Materials, 2017, 27(9): 1606066. [36] JUNG Y H, PARK B, KIM J U, et al. Bioinspired electronics for artificial sensory systems[J]. Advanced Materials, 2019, 31(34): 1803637. [37] CAI Y W, ZHANG X N, WANG G G, et al. A flexible ultra-sensitive triboelectric tactile sensor of wrinkled PDMS/MXene composite films for E-skin[J]. Nano Energy, 2021, 81: 105663. [38] GAO Y J, OTA H, SCHALER E W, et al. Wearable microfluidic diaphragm pressure sensor for health and tactile touch monitoring[J]. Advanced Materials, 2017, 29(39): 1701985. [39] YANG T T, XIE D, LI Z H, et al. Recent advances in wearable tactile sensors: Materials, sensing mechanisms, and device performance[J]. Materials Science and Engineering: R: Reports, 2017, 115: 1-37. [40] ZHONG W B, LIU Q Z, WU Y Z, et al. A nanofiber based artificial electronic skin with high pressure sensitivity and 3D conformability[J]. Nanoscale, 2016, 8(24): 12105-12112. [41] PARK J, KIM M, LEE Y, et al. Fingertip skin-inspired microstructured ferroelectric skins discriminate static/dynamic pressure and temperature stimuli[J]. Science Advances, 2015, 1(9): e1500661. [42] LEI Z Y, WU P Y. A supramolecular biomimetic skin combining a wide spectrum of mechanical properties and multiple sensory capabilities[J]. Nature Communications, 2018, 9(1): 1134. [43] BOUTRY C M, NEGRE M, JORDA M, et al. A hierarchically patterned, bioinspired e-skin able to detect the direction of applied pressure for robotics[J]. Science Robotics, 2018, 3(24): eaau6914. [44] ZHU B, LIU J Z, CAULEY S F, et al. Image reconstruction by domain-transform manifold learning[J]. Nature, 2018, 555(7697): 487-492. [45] KO H C, STOYKOVICH M P, SONG J Z, et al. A hemispherical electronic eye camera based on compressible silicon optoelectronics[J]. Nature, 2008, 454(7205): 748-753. [46] GU L L, PODDAR S, LIN Y J, et al. A biomimetic eye with a hemispherical perovskite nanowire array retina[J]. Nature, 2020, 581(7808): 278-282. [47] ZHANG L, PASTHUKOVA N, YAO Y F, et al. Self-suspended nanomesh scaffold for ultrafast flexible photodetectors based on organic semiconducting crystals[J]. Advanced Materials, 2018, 30(28): 1801181. [48] DENG W, ZHANG X J, JIA R F, et al. Organic molecular crystal-based photosynaptic devices for an artificial visual-perception system[J]. NPG Asia Materials, 2019, 11: 77. [49] ZHOU F C, ZHOU Z, CHEN J W, et al. Optoelectronic resistive random access memory for neuromorphic vision sensors[J]. Nature Nanotechnology, 2019, 14(8): 776-782. [50] ESCUDER-GILABERT L, PERIS M. Review: Highlights in recent applications of electronic tongues in food analysis[J]. Analytica Chimica Acta, 2010, 665(1): 15-25. [51] KRANTZ-RÜLCKER C, STENBERG M, WINQUIST F, et al. Electronic tongues for environmental monitoring based on sensor arrays and pattern recognition: a review[J]. Analytica Chimica Acta, 2001, 426(2): 217-226. [52] SON M, LEE J Y, KO H J, et al. Bioelectronic nose: an emerging tool for odor standardization[J]. Trends in Biotechnology, 2017, 35(4): 301-307. [53] WASILEWSKI T, GĘBICKI J, KAMYSZ W. Advances in olfaction-inspired biomaterials applied to bioelectronic noses[J]. Sensors and Actuators B: Chemical, 2018, 257: 511-537. [54] GUO L L, WANG T, WU Z H, et al. Portable food-freshness prediction platform based on colorimetric barcode combinatorics and deep convolutional neural networks[J]. Advanced Materials, 2020, 32(45): 2004805. [55] GANCARZ M, MALAGA-TOBOŁA U, ONISZCZUK A, et al. Detection and measurement of aroma compounds with the electronic nose and a novel method for MOS sensor signal analysis during the wheat bread making process[J]. Food and Bioproducts Processing, 2021, 127: 90-98. [56] ZHU J X, CHO M, LI Y T, et al. Biomimetic turbinate-like artificial nose for hydrogen detection based on 3D porous laser-induced graphene[J]. ACS Applied Materials & Interfaces, 2019, 11(27): 24386-24394. [57] WU C S, DU Y W, HUANG L Q, et al. Biomimetic sensors for the senses: towards better understanding of taste and odor sensation[J]. Sensors (Basel, Switzerland), 2017, 17(12): 2881. [58] MOHAMADZADE B, HASHMI R M, SIMORANGKIR R B V B, et al. Recent advances in fabrication methods for flexible antennas in wearable devices: state of the art[J]. Sensors (Basel, Switzerland), 2019, 19(10): 2312. [59] PARK J, KIM J, KIM S Y, et al. Soft, smart contact lenses with integrations of wireless circuits, glucose sensors, and displays[J]. Science Advances, 2018, 4(1): eaap9841. [60] DENG W L, YANG T, JIN L, et al. Cowpea-structured PVDF/ZnO nanofibers based flexible self-powered piezoelectric bending motion sensor towards remote control of gestures[J]. Nano Energy, 2019, 55: 516-525. [61] CHU Y, ZHONG J W, LIU H L, et al. Human pulse diagnosis for medical assessments using a wearable piezoelectret sensing system[J]. Advanced Functional Materials, 2018, 28(40): 1803413. [62] HAN O Y, TIAN J J, SUN G L, et al. Self-powered pulse sensor for antidiastole of cardiovascular disease[J]. Advanced Materials, 2017, 29(40): 1703456. [63] TIAN X, LEE P M, TAN Y J, et al. Wireless body sensor networks based on metamaterial textiles[J]. Nature Electronics, 2019, 2(6): 243-251. [64] NAN K W, KANG S D, LI K, et al. Compliant and stretchable thermoelectric coils for energy harvesting in miniature flexible devices[J]. Science Advances, 2018, 4(11): eaau5849. [65] LAI Y C, DENG J N, ZHANG S L, et al. Single-thread-based wearable and highly stretchable triboelectric nanogenerators and their applications in cloth-based self-powered human-interactive and biomedical sensing[J]. Advanced Functional Materials, 2017, 27(1): 1604462. [66] LIU Y Q, SUN N, LIU J W, et al. Integrating a silicon solar cell with a triboelectric nanogenerator via a mutual electrode for harvesting energy from sunlight and raindrops[J]. ACS Nano, 2018, 12(3): 2893-2899. [67] HWANG G T, KIM Y, LEE J H, et al. Self-powered deep brain stimulation via a flexible PIMNT energy harvester[J]. Energy & Environmental Science, 2015, 8(9): 2677-2684. [68] BOUTRY C M, BEKER L, KAIZAWA Y, et al. Biodegradable and flexible arterial-pulse sensor for the wireless monitoring of blood flow[J]. Nature Biomedical Engineering, 2019, 3(1): 47-57. [69] GAO X Y, WU J G, YU Y, et al. Giant piezoelectric coefficients in relaxor piezoelectric ceramic PNN-PZT for vibration energy harvesting[J]. Advanced Functional Materials, 2018, 28(30): 1706895. [70] WANG H, WANG J H, HE T, et al. Direct muscle stimulation using diode-amplified triboelectric nanogenerators (TENGs)[J]. Nano Energy, 2019, 63: 103844. [71] DUAN J J, FENG G, YU B Y, et al. Aqueous thermogalvanic cells with a high Seebeck coefficient for low-grade heat harvest[J]. Nature Communications, 2018, 9: 5146. [72] LIN Y J, CHEN J Q, TAVAKOLI M M, et al. Printable fabrication of a fully integrated and self-powered sensor system on plastic substrates[J]. Advanced Materials, 2019, 31(5): 1804285. [73] DONG L, WEN C S, LIU Y, et al. Piezoelectric buckled beam array on a pacemaker lead for energy harvesting[J]. Advanced Materials Technologies, 2019, 4(1): 1800335. [74] LI N, YI Z R, MA Y, et al. Direct powering a real cardiac pacemaker by natural energy of a heartbeat[J]. ACS Nano, 2019, 13(3): 2822-2830. [75] 王童, 温娟, 吕康, 等. 仿生生物感官的感存算一体化系统[J]. 物理学报, 2022, 71(14): 148702. WANG T, WEN J, LÜ K, et al. Bio-inspired sensory systems with integrated capabilities of sensing, data storage, and processing[J]. Acta Physica Sinica, 2022, 71(14): 148702. [76] LI S, LYU H B, LI J A, et al. Multiterminal ionic synaptic transistor with artificial blink reflex function[J]. IEEE Electron Device Letters, 2021, 42(3): 351-354. [77] LI S, LYU H B, ZHOU Y L, et al. Artificial reflex arc: an environment-adaptive neuromorphic camouflage device[J]. IEEE Electron Device Letters, 2021, 42(8): 1224-1227. [78] YI Z K, ZHANG Y L, PETERS J. Biomimetic tactile sensors and signal processing with spike trains: a review[J]. Sensors and Actuators A: Physical, 2018, 269: 41-52. [79] 蒋子寒, 柯硕, 祝影, 等. 柔性神经形态晶体管及其仿生感知应用[J]. 物理学报, 2022, 71(14): 147301. JIANG Z H, KE S, ZHU Y, et al. Flexible neuromorphic transistors and their biomimetric sensing application[J]. Acta Physica Sinica, 2022, 71(14): 147301. [80] KIM Y, CHORTOS A, XU W T, et al. A bioinspired flexible organic artificial afferent nerve[J]. Science, 2018, 360(6392): 998-1003. [81] ISKAROUS M M, THAKOR N V. E-skins: biomimetic sensing and encoding for upper limb prostheses[J]. Proceedings of the IEEE, 2019, 107(10): 2052-2064. [82] MICHAUD H O, DEJACE L, DE MULATIER S, et al. Design and functional evaluation of an epidermal strain sensing system for hand tracking[C]//Proceedings of 2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). Piscataway: IEEE Press, : 3186-3191. [83] DEJACE L, LAUBEUF N, FURFARO I, et al. Gallium-based thin films for wearable human motion sensors[J]. Advanced Intelligent Systems, 2019, 1(5): 1900079. [84] OH S, CHO J I, LEE B H, et al. Flexible artificial Si-In-Zn-O/ion gel synapse and its application to sensory-neuromorphic system for sign language translation[J]. Science Advances, 2021, 7(44): eabg9450. [85] KIM S H, BAEK G W, YOON J, et al. A bioinspired stretchable sensory-neuromorphic system[J]. Advanced Materials, 2021, 33(44): 2104690. [86] LIU H C, DONG W, LI Y F, et al. An epidermal sEMG tattoo-like patch as a new human–machine interface for patients with loss of voice[J]. Microsystems & Nanoengineering, 2020, 6: 16. [87] ZHAN Y Q, MEI Y F, ZHENG L R. Materials capability and device performance in flexible electronics for the Internet of Things[J]. J Mater Chem C, 2014, 2(7): 1220-1232. |
[1] | Jing WU, Sheng LI, Jing ZHANG, Ming XIN, Ruowen TAO, Zhou ZHOU, Lijia PAN, Yi SHI. New flexible sensor for the internet of things [J]. Chinese Journal on Internet of Things, 2023, 7(2): 1-14. |
[2] | Junge LIANG, Yiran SONG, Yangfan SUN, Yingying JI, Lijia PAN, Yi SHI. Research progress of human health IoT based on wearable and implantable techniques [J]. Chinese Journal on Internet of Things, 2023, 7(2): 26-34. |
[3] | Guanglei GENG, Bo GAO, Ke XIONG, Pingyi FAN, Yang LU, Yuwei WANG. A survey of federated learning for 6G networks [J]. Chinese Journal on Internet of Things, 2023, 7(2): 50-66. |
[4] | Nongyu WEI, Zilong JIANG, Fangjiong CHEN. AODV protocol for acoustic-radio integrated network based on location information and energy balance [J]. Chinese Journal on Internet of Things, 2023, 7(1): 27-36. |
[5] | Bin SHEN, Yinbo LI, Xiaowei LIANG. Spectrum access control for cognitive internet of things users based on enhanced weighted centroid localization [J]. Chinese Journal on Internet of Things, 2023, 7(1): 93-108. |
[6] | Jing WANG, Lesheng HE, Zhonghong LI, Luchi LI, Hang YANG. Software and hardware co-design of lightweight authenticated ciphers ASCON for the internet of things [J]. Chinese Journal on Internet of Things, 2022, 6(4): 139-148. |
[7] | Weijin JIANG, Tiantian LUO, Ying YANG, En LI, Wenying ZHOU. Private data access control model based on block chain technology in the internet of things environment [J]. Chinese Journal on Internet of Things, 2022, 6(4): 169-182. |
[8] | Fangyuan XING, Shibo HE, Mingyang SUN, Jiming CHEN. Carbon emission monitoring based on internet of things with cloud-tube-edge-end structure [J]. Chinese Journal on Internet of Things, 2022, 6(4): 53-64. |
[9] | Jun SUN, Shangweikang ZHAO. Energy-saving computation offloading scheme based on Sarsa algorithm in industrial internet of things [J]. Chinese Journal on Internet of Things, 2022, 6(3): 82-90. |
[10] | Zaichen ZHANG, Xiaohu YOU, Jian DANG, Liang WU, Bingcheng ZHU, Ji CHEN, Lei WANG. Optical wireless communication and internet of things [J]. Chinese Journal on Internet of Things, 2022, 6(3): 1-13. |
[11] | Nuo HUANG, Weijie LIU, Chen GONG. Industrial IoT oriented petahertz communication [J]. Chinese Journal on Internet of Things, 2022, 6(3): 37-46. |
[12] | Yang LIU, Cuican LI, Mugen PENG. Low-power internet of underwater things: vision and key technologies [J]. Chinese Journal on Internet of Things, 2022, 6(2): 1-9. |
[13] | Jing YANG, Jinfeng XIE, Yi CHEN. A study of testing-index and certification systems of IoT terminals for smart city in China [J]. Chinese Journal on Internet of Things, 2022, 6(2): 26-37. |
[14] | Dan LUO, Ruzhi XU, Zhitao GUAN. Differential privacy budget optimization based on deep learning in IoT [J]. Chinese Journal on Internet of Things, 2022, 6(2): 65-76. |
[15] | Zihui LUO, Chengling JIANG, Liang LIU, Xiaolong ZHENG, Huadong MA. Research on deep reinforcement learning based intelligent shop scheduling method [J]. Chinese Journal on Internet of Things, 2022, 6(1): 53-64. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||
|