Lecture

Noise Reduction in Biomedical Instrumentation

Related lectures (32)

Explores negative feedback in analog circuits, focusing on desensitizing gain, reducing distortion, controlling noise, and extending bandwidth.

Chopper Stabilization Techniques

Explores Chopper Stabilization (CHS) technique in Analog IC Design, focusing on noise reduction and offset minimization.

Voltage Summator: Frequency-Independent Inverter Assembly

Explores the design of a voltage summator with a frequency-independent inverter assembly.

Mixed-signal circuits: Comparators

Explores high-speed comparators, basic topologies, and clocked comparators in mixed-signal circuits.

Neural Recording Techniques and Systems

Explores neural recording techniques, systems, amplifiers, and high-value resistor integration for low-power optimization.

Low-power Analog IC Design: Amplifiers

Covers the design of low-power analog integrated circuits, focusing on operational transconductance amplifiers (OTAs) and operational amplifiers (OPAMPs).

Electrocardiogram Amplification

Explores the challenges of amplifying ECG signals while rejecting interference, emphasizing precise component matching and common mode rejection techniques.

Common Mode Voltage in Biomedical Instrumentation

Explores the origins of common mode voltage in biomedical instrumentation and techniques to reduce it, including the Driven Right Leg circuit.

Basic Two-stage OPAMP: Small-signal Analysis

Covers the design and analysis of basic two-stage operational amplifiers (OPAMPs) with a focus on small-signal analysis and offset reduction techniques.

Operational Amplifiers: Comparators and Oscillators

Explores operational amplifiers, comparators, and oscillators, emphasizing their design and applications.

Noise Reduction Techniques in Analog Circuits

Explores noise and offset reduction techniques in analog circuits, focusing on Autozero and Chopper Stabilization.

Front End Electronics: Noise and Offset Reduction

Explores front end integrated electronics design for low noise and offset in sensors, covering fundamental aspects and advanced noise reduction techniques.

Electrocardiogram & Photoplethysmogram: Circuits Design & Analysis

Explores circuit design for ECG and PPG measurements, covering impedance, interference sources, differential amplifiers, and infinite input impedance.

Voltage Follower: Applications and Frequency Response

Explores the voltage follower circuit, its applications, and frequency response in electronic systems.

Experimental Results Presentation: Tabor Experiment Analysis

Covers the analysis of experimental results from the Tabor experiment, focusing on voltage measurements and circuit design.

Designing NMOS Amplifiers: Key Parameters and Techniques

Covers the design principles and key parameters for NMOS amplifiers, focusing on transconductance and gain optimization.

Digital Logic Circuits: CMOS and Verilog Design

Discusses digital logic circuits, CMOS technology, and Verilog for circuit design.

Noise Calculation in Circuits

Covers noise analysis in circuits, including small-signal and input-referred noise, with examples of amplifiers and filters.

Circuits: Innovations and Limitations

Delves into circuit innovations reshaping the future, surpassing believed limitations with recent designs of high-power-density DC-DC converters, noise-efficient sensor interfaces, and wide-bandwidth phase-locked loops.

QUCS software basics

Covers the basics of the free Quite Universal Circuit Simulator (QUCS) software for circuit simulation.