• Integrator Buffered CDS (IBC)
• Flicker Noise Cancellation
• Electrical Impedance Spectroscopy (EIS)
• Digital to Analog Converter (DAC)
• Differential Bandgap Voltage Reference
• Correlated Double Sampling (CDS)
• Analog Front End (AFE)
• Amplifier
• Offset Cancellation
• On-Chip Sinusoidal Wave Generator
• Sensor Interface
• Switched Capacitor (SC)

In this Ph.D. thesis an integrated circuit for Electrical Impedance Spectroscopy (EIS) systems is reported. The proposed interface circuit constitutes an Analog Front End (AFE) suitable also for other measurement techniques, such as voltammetry, and allows both two-terminal and four-terminal sensing. A stimulus generator and a readout chain are the core of the system. The stimulus generator is based on a novel architecture for switched capacitor Digital-to-Analog Converters (DACs), which is capable of producing a continuous-time output signal and allows offset cancellation and low frequency noise reduction. The readout chain consists of a fully differential instrumentation amplifier based on an original topology which embodies chopper modulation for offset and flicker noise reduction. The in-amp includes an embedded demodulator which extracts in-phase and quadrature component of the input signal. An improved version of the technique for offset cancellation and flicker noise reduction, used for the switched capacitor DAC, is applied to other essential blocks which are a bandgap voltage reference and a differential-to-single ended converter.
Such technique, termed Integrator Buffered CDS (IBC) because employs a first stage with correlated double sampling which is buffered by an integrator, is finally applied to develop an alternative architecture for very compact operational amplifiers.