A K-Band Complex Permittivity Sensor for Biomedical Applications in 130-nm SiGe BiCMOS

“…, which agrees with the tangent at  mut = 1 of the numerical curve obtained through (10), shown in Fig. 4(a).…”

“…3. The results obtained with the complete analytical expression (9) and with the numerical zerovalue contour (10) are overlapped in all cases. In agreement with the previous derivations, the sensitivity increases when reducing F 1 .…”

“…Some examples are the works [1]- [2], which make use of step-impedance resonators and [3]- [4], which make use of split ring resonators [3]- [4]. On the other hand, the recent works [5]- [9] are based on the detection of phase variations [10]- [12] when exciting the system at a constant frequency. In those sensors, which operate in either transmission or reflection mode, the phase varies in the presence of the MUT.…”

“…On the other hand, the work [13] presents a detailed analysis of oscillators containing a slowwave structure [14]- [18], which enables a low phase-noise spectral density. In fact, oscillator-based sensors [19]- [29] have the advantage of a self-sustained operation, in which the MUT variations give rise to a change in the oscillation amplitude and frequency [21]- [22], easily measured with the aid of amplitude or frequency detection interfaces; for instance, frequency variations can be detected from the control voltage of a synthesizer and amplitude variations by means of a power detector or through the control voltage of a feedback loop [10], [21], [25]- [28].…”

Oscillators Based on Step-Impedance and Slow Wave Transmission Lines for Sensing Applications

“…, which agrees with the tangent at  mut = 1 of the numerical curve obtained through (10), shown in Fig. 4(a).…”

“…3. The results obtained with the complete analytical expression (9) and with the numerical zerovalue contour (10) are overlapped in all cases. In agreement with the previous derivations, the sensitivity increases when reducing F 1 .…”

“…Some examples are the works [1]- [2], which make use of step-impedance resonators and [3]- [4], which make use of split ring resonators [3]- [4]. On the other hand, the recent works [5]- [9] are based on the detection of phase variations [10]- [12] when exciting the system at a constant frequency. In those sensors, which operate in either transmission or reflection mode, the phase varies in the presence of the MUT.…”

“…On the other hand, the work [13] presents a detailed analysis of oscillators containing a slowwave structure [14]- [18], which enables a low phase-noise spectral density. In fact, oscillator-based sensors [19]- [29] have the advantage of a self-sustained operation, in which the MUT variations give rise to a change in the oscillation amplitude and frequency [21]- [22], easily measured with the aid of amplitude or frequency detection interfaces; for instance, frequency variations can be detected from the control voltage of a synthesizer and amplitude variations by means of a power detector or through the control voltage of a feedback loop [10], [21], [25]- [28].…”

Oscillators Based on Step-Impedance and Slow Wave Transmission Lines for Sensing Applications

“…Fig. 20(a) shows the results for healthy tissue that yields an output voltage of 0.5 V, while the calcified The encouraging results from the abovementioned experiments have led to an implementation of a high-frequency K-band permittivity sensor in a commercial 130-nm BiCMOS technology [140] for wider application in the detection of biomaterials. Fig.…”

Integrated Millimeter-Wave and Terahertz Analyzers for Biomedical Applications

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