Fig 1.
Dual-band antenna configuration with oriented view including compact dimensions.
Fig 2.
Radiating patch printed on top-plane.
Fig 3.
Ground dimensions.
Table 1.
Optimized parameters.
Fig 4.
Evolution Aa.
Fig 5.
Evolution Ab.
Fig 6.
Evolution Ac.
Fig 7.
S11 of Antenna Aa-Antenna Ac.
Fig 8.
SFDMB at 10.90GHz.
Fig 9.
SFDMB at 15.0GHz.
Fig 10.
SFDMB at 24.0GHz.
Fig 11.
SFDMB at 26.0GHz.
Fig 12.
SFDMB at 28.0GHz.
Fig 13.
SFDMB at 60.0GHz.
Fig 14.
Parametric study of H.
Fig 15.
Parametric study of BL.
Fig 16.
Parametric study of SL.
Fig 17.
S11 comparison of bending of antenna.
Fig 18.
Isometric view of the proposed antenna placed above the Phantom tissue.
Fig 19.
Front-view of the antenna with tissue model.
Fig 20.
Placement of the antenna at 5.00mm distance abive tissue model.
Fig 21.
SAR analysis at 10.90GHz.
Fig 22.
SAR analysis at 15.0GHz.
Fig 23.
SAR analysis at 24.0GHz.
Fig 24.
SAR analysis at 26.0GHz.
Fig 25.
SAR analysis at 28.0GHz.
Fig 26.
SAR analysis at 60.0GHz.
Table 2.
RF properties of the phantom-human-tissue.
Table 3.
SARDWMB values.
Fig 27.
Equivalent circuit model for Band1 (8.73GHz-33.05GHz).
Fig 28.
S11 (Band1).
Fig 29.
Equivalent circuit model for Band2 (52.46GHz-71.09GHz).
Fig 30.
S11 (Band2).
Fig 31.
Re-Img. graph.
Table 4.
RLC values of equivalent-circuit-model.
Fig 32.
Dual-port MIMODWMB antenna configuration Isometric view.
Fig 33.
Dual-port MIMODWMB antenna configuration front-view.
Fig 34.
S11/S22 (without and with de-coupling structure).
Fig 35.
S12/S21 (without and with de-coupling structure).
Fig 36.
SFDDWMB without de-coupling structure.
Fig 37.
SFDDWMB with de-coupling structure.
Fig 38.
Time-domain analysis in face-to-face orientation.
Fig 39.
Time-domain analysis in side-to-side orientation.
Fig 40.
Impulse-responseDWMB.
Fig 41.
Group-DelayDWMB (FF and SS).
Fig 42.
Four-Port MIMODWMB antenna with perspective view.
Fig 43.
Four-Port MIMODWMB antenna with front-ground view.
Fig 44.
Four-Port MIMODWMB antenna prototype front-view.
Fig 45.
Four-Port MIMODWMB antenna prototype ground-view.
Fig 46.
Simulated reflection-coefficients S-parameters.
Fig 47.
Simulated transmission-coefficients S-parameters.
Fig 48.
Measured reflection-coefficients S-parameters.
Fig 49.
Measured transmission-coefficients S-parameters.
Fig 50.
Surface-current-densityDWMB distribution without de-coupling structure.
Fig 51.
Surface-current-densityDWMB distribution with de-coupling structure.
Fig 52.
Simulated ECCDWMB.
Fig 53.
Measured ECCDWMB.
Fig 54.
Simulated DGDWMB.
Fig 55.
Measured DGDWMB.
Fig 56.
Simulated TARCDWMB.
Fig 57.
Measured TARCDWMB.
Fig 58.
Simulated CCLDWMB.
Fig 59.
Measured CCLDWMB.
Fig 60.
Simulated-measured peak gain & radiation efficiency.
Fig 61.
Photograph of the antenna within the anechoic-chamber.
Fig 62.
Simulated-measured 2-D radiation pattern at 10.0GHz.
Fig 63.
Simulated-measured 2-D radiation pattern at 15.0GHz.
Fig 64.
Simulated-measured 2-D radiation pattern at 24.0GHz.
Fig 65.
Simulated-measured 2-D radiation pattern at 26.0GHz.
Fig 66.
Simulated-measured 2-D radiation pattern at 28.0GHz.
Fig 67.
Simulated-measured 2-D radiation pattern at 60.0GHz.
Fig 68.
SAR analysis at 10.0GHz.
Fig 69.
SAR analysis at 15.0GHz.
Fig 70.
SAR analysis at 24.0GHz.
Fig 71.
SAR analysis at 26.0GHz.
Fig 72.
SAR analysis at 28.0GHz.
Fig 73.
SAR analysis at 60.0GHz.
Fig 74.
Radius Calculation.
Fig 75.
Conformal analysis at SAR analysis at 0°.
Fig 76.
Conformal analysis at SAR analysis at 30°.
Fig 77.
Conformal analysis at SAR analysis at 45°.
Fig 78.
S11-parameter (conformal).
Fig 79.
VNA screenshot with bending of the MIMO antenna.
Table 5.
Bandwidth for bending angles of the antenna.
Table 6.
Comparison of the proposed work with previously published work.