Related Concept Videos
Upsampling
Sampling Theorem
Sampling Continuous Time Signal
In the...
Aliasing
If the sampling frequency is below the Nyquist rate, these replicas overlap, preventing the original...
Time and frequency -Domain Interpretation of Phase-lag Control
Phase-lag controllers do not place a pole at zero, but instead influence the steady-state error by amplifying any...
Reconstruction of Signal using Interpolation
You might also read
Related Articles
Articles linked to this work by shared authors, journal, and citation graph.
Real-time FMR lorentzian visualization through a novel synchronous VNA-FMR measurement apparatus.
Role of the mononuclear cell infiltrate in Graves' orbitopathy (GO): results of a large cohort study.
Related Experiment Video
Updated: Jul 12, 2025

Measurement of Scattering Nonlinearities from a Single Plasmonic Nanoparticle
Published on: January 3, 2016
Dual-phase digital lock-in implementation based on Nyquist rate and sampling subtraction.
B Ricobom1, M Nardi1, M Bonfim1
1Laboratory of Magnetism, Measurement and Instrumentation, Electrical Engineering Department, Federal University of Parana (UFPR), Curitiba, Brazil.
This study presents a simple, low-cost dual-phase lock-in amplifier (LIA) implementation using microcontrollers. The method efficiently detects weak signals and complex quantities in noisy environments.
Area of Science:
- Electronics
- Signal Processing
- Instrumentation
Background:
- Lock-in amplifiers (LIAs) are crucial for detecting low-amplitude signals in noisy laboratory settings.
- LIAs utilize synchronous detection and phase-sensitive detection to extract signal components.
Purpose of the Study:
- To present a simple, low computational-cost implementation of a dual-phase lock-in amplifier.
- To demonstrate the use of readily available microcontrollers for LIA implementation.
Main Methods:
- Development of a fast algorithm for dual-phase lock-in amplification.
- Implementation on low-cost microcontrollers for practical application.
- Testing with diverse signal detection scenarios.
Main Results:
- Successful implementation of a dual-phase LIA with minimal computational cost.
- Demonstrated capability in detecting weak signals and measuring complex quantities.
- Validation through three distinct signal detection examples.
Conclusions:
- The proposed microcontroller-based LIA offers a flexible and cost-effective solution for signal detection.
- The methodology is suitable for various applications, including sound wave analysis, impedance measurements, and weak signal recovery.

