Indian Journal of Science and Technology
Year: 2018, Volume: 11, Issue: 10, Pages: 1-6
S. Palanivel Rajan and S. Suganya
*Author for correspondence
S. Palanivel Rajan,
Department of Electronics and Communication Engineering, M. Kumarasamy College of Engineering (Autonomous), Karur, Thalavapalayam − 639113, Tamilnadu, India; [email protected]
Objectives: To design and produce the loop antenna in order to identify or measure the brain stroke detection between the applicable frequency range of 300 MHz to 3 GHz, during in a usual and unusual conditions. A design terminology for embedded antennas has been imitated on the malleable or flexible substrate which is based on the process of Electro Cartography (ECOG). Methods/Statistical Analysis: The brain stroke detection techniques are analyzed through the Real time network link interfaces between the human brain and automated cosmetic surgery, that can implement the illusion of many inmates anguishing or suffering from depression, anesthetic cord or spinal cord injury, stroke, and alternatively damaging neurological breast implants in order to use cosmetic surgery appendage in the equivalent manner as organic limbs. This is managed with some related appliances that transmit the formation or attention into the movement of Brain Machine Interface (BMI) systems. Findings: The loop antenna generally uses the frequency range of up to 3GHz and based on this limited frequency, only the fixed frequency is mainly applicable for this concept around 400 MHz. During normal conditions and in abnormal conditions, the frequency range is acceptable within the range of 300 MHz to 3 GHz. For a fixed value of frequency it commonly provides low directivity and coefficient based on permittivity and conductivity. Here, the antenna is usually designed for a maximal link gain networks beyond the human scalp to effectively increase the embed power. A simulation result of this loop antenna implies that enhancing the communication or transmission frequency together along with an antenna calculation can provide absolute power and voltage signal to the required embedded antennas. Application/Improvements: This is mainly applicable for cosmetic surgery limbs, where such systems desire neurological sensors for neural reporting and brain incentive, and also it provides an improvement in a path to a peripheral unit that figure out the neural link data and restricts the imitation actuators.
Keywords: Brain Machine Interface (BMI), Implanted Antenna, Radio Frequency Identification (RFID), Specific Absorption Rate (SAR), Tiny Loop Antennas
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