G. Vasudeva, B. V. Uma,
Volume 18, Issue 3 (9-2022)
Abstract
Successive approximation register (SAR) analog to digital converter (ADC) architecture comprises submodules such as comparator, digital to analog converters (DAC), and SAR logic. Each of these modules imposes challenges as the signal makes transition from analog to digital and vice-versa. Design strategies for optimum design of circuits considering 22nm FinFET technology meeting area, timing, power requirements, and ADC metrics are presented in this work. Operational Transconductance Amplifier (OTA) based comparator, 12-bit two-stage segmented resistive string DAC architecture, and low power SAR logic are designed and integrated to form the ADC architecture with a maximum sampling rate of 1 GS/s. Circuit schematic is captured in cadence environment with optimum geometrical parameters and performance metrics of the proposed ADC are evaluated in MATLAB environment. Differential nonlinearity and integral nonlinearity metrics for the 12-bit ADC are limited to +1.15/-1 LSB and +1.22/-0.69 LSB respectively. ENOB of 10.1663 with SNR of 62.9613 dB is achieved for the designed ADC measured for conversion of input signal of 100 MHz with 20dB noise. ADC with sampling frequency up to 1 GSps is designed in this work with low power dissipation of less than 10 mW.
Godday Biowei, Sulaiman Adeniyi Adekola, Kamoli Akinwale Amusa,
Volume 20, Issue 3 (9-2024)
Abstract
Presented in this paper is an evaluation of human tissue penetration by millimeter wave (mmW) energy, particularly at 30, 35, 40 and 45 GHz. Numerical simulations show that the penetration depths in the tissue are (0.1000, 0.0937, 0.08869 and 0.08882) mm at the aforementioned frequency, respectively. It is also demonstrated that all mmW at those frequencies attenuate to zero at the epidermis which is the layer adjacent to the skin surface, without getting into the dermis which is the next layer. Crucially, these discoveries present fresh, previously unmentioned data within the current research literature. Furthermore, at the lower frequency of 24 GHz, computer simulations presented show that the propagating wave penetrates deeper (depth of 0.12 mm) and attenuates to zero at the dermis. This shows that the depth of penetration increases further at lower frequencies which strongly conforms to the principles of physical reasoning, thereby bolstering the reliability of the findings presented in this paper. The results collectively indicate that the absorption of mmW into the human tissue have limited significance when assessing compliance with electromagnetic field standards at mmW frequencies. It is reinforced in this paper why the human skin reduces the harmful effects of ultra-violet radiation. To lend credence to our formulation, certain aspects of the results obtained in this investigation when compared with similar results in the literature, show good agreements.
