Sage Journals: Discover world-class research

Abstract

BACKGROUND:

Antennas for the microwave imaging system are large which results in higher radiation, manufacturing cost, poor radiation characteristics and it will be difficult to locate on breast tissues.

OBJECTIVE:

We propose a wearable ultra-wide band antenna for use in the diagnosis of breast cancer bio-medical applications.

METHODS:

The antenna has been fabricated on 1.6 mm FR4 substrate with a dimension of 28 $\times$ 14.4 mm ${}^{2}$ and can operate between 2 GHz–12 GHz with $S_{11}<-$ 10 dB with best radiation characteristics. The prototype of the proposed antenna was fabricated and practically tested and the results were found to be consistent with the simulated results. The proposed UWB antenna is intended to radiate and receive information covering the entire spectrum from 3 GHz to 13 GHz. For good impendence matching throughout the larger spectrum, the defected ground structure (diamond shape) was exploited. All the dimensions of the proposed design are confirmed by parametric study and optimization.

RESULTS:

The maximum simulated efficiency was ranging from 80 to 84% in the desired operating frequency. The maximum Specific Absorption Rate of the proposed antenna was 0.98 W/Kg. Therefore, the proposed UWB antenna could be the right structure for breast cancer diagnosis in terms of SAR. The antenna was found to have a substantial radiation efficiency of around 78%–84% in the desired operating bandwidth. The overall realized gain of the proposed UWB antenna was seen ranging from 1.8–4.2 dB which is sufficient for bio-medical applications.

CONCLUSION:

The breast phantom was modeled for the validation of the performance of the antenna and SAR was analyzed. The value of SAR of the designed antenna was observed at about 0.98 W/Kg, which is suitable for medical applications.

Keywords

Antenna breast tumor medical radiation pattern SAR

Get full access to this article

View all access options for this article.

References

Fass

. Imaging and cancer: A review. Mol. Oncol. 2008; 2(2): 115-52.

Gallego

. Riesgosderivados de la exposicion a dosisbajas de radiacion ionizante. Revista de Salud Ambiental. 2010; 10(1–2): 43-8.

Nnez

. Efectosbiologicos de las radiaciones-dosimetra. Escuela Universitaria de TecnologiaMedicaUdelaRComite de Tecnologos de ALASBIMN, Montevideo, Uruguay, 2008.

Surowiec

Stuchly

Barr

Swarup

AASA

. Dielectric properties of breast carcinoma and the surroundingtissues. IEEE Trans. Biomed. Eng. 1988; 35(4): 257-63.

Grzegorczyk

Meaney

Kaufman

Paulsen

. Fast 3-D tomographic microwave imaging for breast cancer detection. IEEE Trans. Med. Imaging. 2012; 31(8): 1584-92.

Pagliari

Pulimeno

Vacca

Tobon

Vipiana

Casu

, et al. A low-cost, fast, and accurate microwave imaging system for breast cancer detection. IEEE Biomedical Circuits and Systems Conference (BioCAS), 2015; pp. 1-4.

Afifi

Abdel-Rahman

Allam

El-Hameed

. A compact ultra-wideband monopole antenna for breast cancer detection. IEEE 59𝑡ℎ International Midwest Symposium on Circuits and Systems (MWSCAS), 2016; pp. 1-4.

Fear

Meaney

Stuchly

. Microwaves for breast cancer detection? IEEE Potentials. 2003; 22(1): 12-8.

Brovoll

Berger

Paichard

Aardal

Lande

Hamran

. Time-lapse imaging of human heart motion with switched array UWB radar. IEEE Trans. Biomed. Circuits Syst. 2014; 8(5): 704-15.

10.

Xie

Guo

Stoica

. Multistatic adaptive microwave imaging for early breast cancer detection. IEEE Trans. Biomed. Eng. 2006; 53(8): 1647-57.

11.

Davis

Hagness

Van der Weide

Van Veen

. Microwave imaging via space-time beamforming: Experimental investigation of tumor detection in multilayer breast phantoms. IEEE Trans. Microw. Theory Tech. 2004; 52(8): 1856-65.

12.

Joines

Dhenxing

Jirtle

. The measured electrical properties of normal and malignant human tissues from 50 to 900 MHz. Med. Phys. 1994; 21: 547-50.

13.

John

. 3D Active Microwave Imaging System for Breast Cancer Screening. Dissertation, Duke University. Retrieved from https//hdl.handle.net/10161/924.

14.

Lalitha

Manjula

Krishnan

. Design of UWB Vivaldi Antenna for Stroke Detection and Monitoring Based on Qualitative Microwave Imaging Technique. Ilkogretim Online. 2021; 20(1): 2335-41.

15.

Sreenivasa Rao

Govardhani

. A Triple band – notched UWB antenna for Microwave Imaging Applications. International Conference on Computer Communication and Informatics (ICCCI), 2021.

16.

Vijayasarveswari

Andrew

Jusoh

Sabapathy

Raof

RAA

Yasin

MNM

Ahmad

Khatun

Rahim,

. Multistage feature selection (MSFS) algorithm for UWB based early breast cancer size prediction. PLOS One, 2021.

17.

Pradeep

Thippesha

Abhishek

Angadi

Swathi

Vanajakshi

. Design and analysis of wearable microstrip patch antenna applied for breast cancer detection. International Res J Eng Technol (IRJET), 2020; 07(08).

18.

Ruan

Ding

Wang

Sun

Houming

. A study on the relationships among character strengths, perceived social support and subjective well-being of breast cancer patients. J. Med. Imaging Health Inf. 2021; 11: 1967-72.

19.

Srikanth

, et al. A slotted UWB monopole antenna with truncated ground plane for breast cancer detection. Alexandria Engineering Journal. 2020; 59(5): 3767-80.

20.

Alsharif

Çetin

. Wearable microstrip patch ultra-wide band antenna for breast cancer detection. IEEE 41𝑠𝑡 International Conference on Telecommunications and Signal Processing (TSP), 2018.

21.

Katbay

, et al. Miniature antenna for breast tumor detection. IEEE 13𝑡ℎ International New Circuits and Systems Conference (NEWCAS), 2015.

22.

Wang

Bin

. Design of ultra-wideband MIMO antenna for breast tumor detection. International Journal of Antennas and Propagation. 2012; (2012).

23.

Zastrow

Davis

Lazebnik

Kelcz

Van Veen

Hagness

. Development of anatomically realistic numerical breast phantoms with accurate dielectric properties for modeling microwave interactions with the human breast. IEEE Trans. Biomed. Eng. 2008; 55(12): 2792-800.

24.

Sill

Williams

Fear

Frayne

Okoniewski

. Realistic breast models for second generation tissue sensing adaptive radar system. European Conf. Antennas and Propagation (EuCAP), Edinburgh, U.K., 2007.

25.

Tuncay

Akduman

. Realistic microwave breast models through T1-weighted 3-D MRI data. IEEE Trans. Biomed. Eng. 2015; 62(2): 688-98.

26.

University of Wisconsin Cross-Disciplinary Electromagnetics Laboratory. Numerical breast phantom repository. [Online].

27.

American College of Radiology. Breast Imaging Reporting and Data System (BI-RADS) Atlas, 4th ed. Reston, VA: Amer. Coll. Radiol., 2003.

A compact diamond shaped ultra-wide band antenna system for diagnosing breast cancer