Add to ORKGIn this paper, we study the wave propagation within various lossy homogeneous human tissues such as the muscle tissue, brain, skin, and the fat layer at 2.4 GHz using insulated dipole antennas. Path loss (PL) in these tissues is determined by means of measurements and simulations, based on which suitable path loss models are proposed. By understanding the path loss within the human body one can establish optimal communication between the antennas embedded within it. We further investigate the influence of the insulation thickness of the insulated dipoles on the antenna resonance frequency
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
In this paper, we investigate multilayered lossy and heterogeneous media for wireless body area netw...
In this paper, we study the wave propagation within various lossy homogeneous human tissues such as ...
A wireless body area network (WBAN) consists of a wireless network with devices placed close to, att...
Proposed is the first in-body path loss model in homogeneous human muscle tissue at 2.4 GHz for impl...
Proposed for the first time is an in-body path loss model for homogeneous human muscle and head tiss...
The path loss between insulated dipole antennas in homogeneous human muscle tissue is investigated a...
A wireless body area network (WBAN) consists of a wireless network with devices placed close to, att...
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
The human body can act as a medium for the transmission of electromagnetic waves in the wireless bod...
A multi-implant scenario is considered using insulated dipole antennas for specific locations such a...
In this paper, the scattering parameters of two dipoles placed closely to a flat, homogeneous, biolo...
In vivo wireless body area networks (WBANs) and their associated technologies are shaping the future...
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
In this paper, we investigate multilayered lossy and heterogeneous media for wireless body area netw...
In this paper, we study the wave propagation within various lossy homogeneous human tissues such as ...
A wireless body area network (WBAN) consists of a wireless network with devices placed close to, att...
Proposed is the first in-body path loss model in homogeneous human muscle tissue at 2.4 GHz for impl...
Proposed for the first time is an in-body path loss model for homogeneous human muscle and head tiss...
The path loss between insulated dipole antennas in homogeneous human muscle tissue is investigated a...
A wireless body area network (WBAN) consists of a wireless network with devices placed close to, att...
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
The human body can act as a medium for the transmission of electromagnetic waves in the wireless bod...
A multi-implant scenario is considered using insulated dipole antennas for specific locations such a...
In this paper, the scattering parameters of two dipoles placed closely to a flat, homogeneous, biolo...
In vivo wireless body area networks (WBANs) and their associated technologies are shaping the future...
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
This paper presents numerical modeling and experimental validation of the signal path loss at the 5....
In this paper, we investigate multilayered lossy and heterogeneous media for wireless body area netw...