Fact-checked by Grok 2 weeks ago

Lock-in amplifier

A lock-in amplifier is a specialized electronic instrument designed to detect and measure very small alternating current (AC) signals, often as low as a few nanovolts, that are buried in much larger noise levels by employing phase-sensitive detection to isolate the signal component at a specific reference frequency and phase.^[1] This technique effectively rejects broadband noise and interference at other frequencies, enabling signal-to-noise ratios as high as 300:1 within a 1 Hz bandwidth, making it indispensable for precise measurements in noisy environments.^[2] The core principle of operation involves multiplying the input signal—comprising the desired AC signal plus noise—with a reference signal of the same frequency, typically a clean sine wave, which shifts the desired component to direct current (DC) while converting uncorrelated noise to higher-frequency terms that can be filtered out by a low-pass filter.^[3] Key components include a low-noise preamplifier to boost the input signal, a phase-sensitive detector (often implemented as an analog or digital multiplier), a phase shifter for aligning the reference with the signal, the low-pass filter for averaging, and in modern designs, digital signal processing for enhanced accuracy and features like harmonic detection.^[1] Dual-phase detection, using two orthogonal references 90 degrees apart, allows simultaneous measurement of signal amplitude and phase, providing vector information essential for applications like impedance analysis.^[2] Invented by physicist Robert H. Dicke in the 1940s while at MIT, the lock-in amplifier evolved from early analog designs to commercial availability in 1962 by Princeton Applied Research, and later to digital versions in the 1980s that offer superior dynamic range exceeding 120 dB and narrow bandwidths down to 0.01 Hz.^[4] As of 2025, these instruments operate over wide frequency ranges up to several GHz in advanced models, serving as versatile tools not only for signal recovery but also as vector voltmeters, phase meters, and spectrum analyzers in fields such as physics, chemistry, and engineering.^[5] Their high effective Q-factor, often over 100,000, stems from automatic frequency tracking via phase-locked loops, ensuring robust performance even with drifting signals.^[3]

Overview

Definition and Purpose

A lock-in amplifier is an electronic instrument that employs a known reference signal to detect and measure small alternating current (AC) signals embedded in substantial noise, with the capability to extract signals up to a million times smaller than the surrounding noise levels.^[6]^[7] The primary purpose of a lock-in amplifier is to achieve phase-sensitive detection, which enhances the signal-to-noise ratio (SNR) by selectively correlating the input signal with the reference signal while rejecting uncorrelated noise.^[8]^[6] In its basic workflow, the instrument multiplies the noisy input signal by the reference signal and then applies low-pass filtering to yield a direct current (DC) output proportional to the amplitude of the desired signal component.^[8] Lock-in amplifiers are commonly employed in low-signal experiments where noise overwhelmingly dominates, such as in physics laboratories for precise measurements.^[8]

Historical Development

The origins of the lock-in amplifier trace back to early concepts in phase-sensitive detection during the 1930s, with C. R. Cosens describing a balance-detector for alternating-current bridges that employed phase-sensitive principles to measure small signals amid noise.^[9] This foundational work laid the groundwork for selective amplification techniques in electrical measurements. In the 1940s, developments in radio engineering advanced these ideas, including W. C. Michels' contributions to vacuum tube voltmeters and, with N. L. Curtis, a pentode-based lock-in amplifier design emphasizing high frequency selectivity through heterodyning with a reference signal.^[9] Further refinement came in 1949 with Michels and E. D. Redding's improved synchronous detector, which minimized feedback to enable preamplification and enhanced sensitivity for weak signals.^[10] Practical implementation and widespread attribution are often credited to Robert H. Dicke in the 1940s, who developed the technique for microwave radiometry during his time at Princeton University and the MIT Radiation Laboratory, where it proved essential for detecting faint signals in noisy environments.^[11] Phase-sensitive detection techniques, including those advanced by Dicke, facilitated adoption in fields like low-temperature physics, where lock-in amplifiers enable precise measurements in experiments involving cryogenics and quantum phenomena.^[9] Following World War II, the proliferation of lock-in amplifiers accelerated in the 1950s and 1960s, driven by the advent of transistor technology that enabled more compact and reliable analog implementations.^[12] The first commercial lock-in amplifier, the Model HR-8, was introduced by Princeton Applied Research in 1962, marking a milestone in making the device accessible to researchers beyond specialized labs.^[13]^[14] This era saw analog lock-ins become standard tools in scientific instrumentation due to their ability to reject broadband noise effectively. The transition to digital lock-in amplifiers began in the mid-1980s with the rise of digital signal processing (DSP) techniques, which replaced analog components with computational methods for greater flexibility and precision in demodulation.^[15] By the 1990s, DSP advancements allowed for multi-frequency analysis and improved dynamic range. In the 2000s and beyond, field-programmable gate array (FPGA)-based systems emerged, supporting high-speed operations up to 2 GHz and enabling customizable, real-time processing for demanding applications.^[16] By the 2020s, these systems have integrated with software-defined platforms for enhanced versatility.

Operating Principles

Analog Implementation

Traditional analog lock-in amplifiers rely on discrete electronic components to process weak signals in noisy environments, forming a hardware chain that amplifies, demodulates, and filters the input. The primary components include a preamplifier for initial signal boosting, a double-balanced mixer for phase-sensitive multiplication, and a low-pass filter for averaging the output. The preamplifier, often configured for single-ended or differential voltage inputs or current modes with conversion ratios such as 10^6 V/A, provides high gain while minimizing noise addition at the input stage. Double-balanced mixers, typically implemented using diode rings or field-effect transistors (FETs) for low distortion, ensure isolation between input, reference, and output ports to suppress unwanted signals. The low-pass filter, commonly an RC network or active design with roll-offs of 6 dB/octave (first-order) or 12 dB/octave (second-order), integrates the demodulated signal to yield a DC output. The reference signal, essential for demodulation, is generated either by an internal oscillator producing a sinusoidal waveform (adjustable from low frequencies up to the instrument's range, e.g., 0–2 V rms) or via an external input synchronized to the signal's modulation frequency. In the signal flow, the amplified input undergoes mixing with the reference, resulting in sum and difference frequency components where the difference term contains the desired DC information modulated by the signal's amplitude. Subsequent low-pass filtering extracts this DC component, which is proportional to the input signal's amplitude at the reference frequency, effectively rejecting broadband noise. This hardware-based multiplication acts as a correlation process with the known reference, as explored in the mathematical foundation. Phase alignment is managed through an adjustable phase shifter on the reference channel, allowing fine adjustments (e.g., in tens of millidegrees) or coarse 90° shifts to match the input signal's phase, enabling accurate detection in dual-phase configurations. Analog implementations typically operate with bandwidths limited to the kilohertz range, such as adjustable low-pass cutoffs around 1 kHz, balancing noise reduction with response time. However, they are sensitive to thermal drift in passive components like resistors and capacitors, as well as active elements in amplifiers, which can introduce offset errors over time or temperature changes. These systems are also vulnerable to electromagnetic interference (EMI), including ground loops and line-frequency pickups (50/60 Hz), often mitigated by optional notch filters but requiring careful shielding. Additionally, analog lock-in amplifiers demand manual tuning for phase and gain, lacking the automated calibration of modern alternatives.

Mathematical Foundation

The mathematical foundation of the lock-in amplifier relies on the principle of orthogonality between sine and cosine functions over a finite integration period, which allows the rejection of uncorrelated noise components while preserving the signal at the reference frequency. Specifically, the inner product of sine and cosine waves with different frequencies—or the same frequency but mismatched phases—averages to zero over multiple periods, enabling selective extraction of the desired signal through phase-sensitive multiplication and filtering.^[17] Consider the input signal U_{in}(t) = V_{sig} \sin(2\pi f t + \theta) + n(t), where V_{sig} is the signal amplitude, f is the signal frequency, \theta is the phase, and n(t) represents broadband noise. This signal is multiplied by a reference waveform \sin(2\pi f_{ref} t), assuming f = f_{ref} for lock-in operation. The product yields:

U_{in}(t) \cdot \sin(2\pi f_{ref} t) = \frac{V_{sig}}{2} \cos(\theta) - \frac{V_{sig}}{2} \cos(2 \cdot 2\pi f t + \theta) + n(t) \sin(2\pi f_{ref} t),

where the first term is the DC component proportional to the signal amplitude and phase difference, the second is a high-frequency term at $2f, and the noise term produces components across frequencies. After low-pass filtering, the high-frequency terms are suppressed, leaving the DC term \frac{1}{2} V_{sig} \cos \theta.^[8] The output after low-pass filtering can be expressed more generally as the time-averaged product:

U_{out}(t) = \frac{1}{T} \int_{t-T}^{t} \sin(2\pi f_{ref} s + \varphi) \, U_{in}(s) \, ds,

where T is the integration time (related to the filter's time constant \tau, often T = 4\tau for a first-order filter), and \varphi is a phase offset in the reference. For a matched signal, this integral extracts the DC component, while uncorrelated noise averages to zero due to the orthogonality of the reference waveform with noise frequencies.^[6] For complete signal recovery, dual-phase detection is employed, using two orthogonal references: one in-phase (\sin(2\pi f_{ref} t)) yielding the X output, and one quadrature (\cos(2\pi f_{ref} t)) yielding the Y output. Thus,

X = \frac{1}{2} V_{sig} \cos \theta, \quad Y = \frac{1}{2} V_{sig} \sin \theta.

The signal amplitude is then R = \sqrt{X^2 + Y^2} = \frac{V_{sig}}{2}, and the phase is \theta = \arctan(Y/X), providing both magnitude and phase information independent of the reference phase.^[8]^[6] This mixing process shifts the signal frequency to DC when the reference matches the signal, allowing noise—assumed stationary and uncorrelated—to average to zero over the integration period, as its product with the reference yields zero mean due to orthogonality. The low-pass filter's time constant \tau determines the effective noise bandwidth \Delta f \approx 1/(4\tau), typically set to reduce the bandwidth to less than 1 Hz, achieving signal-to-noise ratios exceeding 10^4 for weak signals buried in noise.^[17]

Digital Implementations

Design and Components

Digital lock-in amplifiers represent an evolution from analog designs, incorporating digital hardware and software to perform phase-sensitive detection with enhanced precision and flexibility. The core architecture typically includes an analog-to-digital converter (ADC) to digitize the input signal and reference, a digital signal processor (DSP) or field-programmable gate array (FPGA) for signal mixing and filtering, and optionally a digital-to-analog converter (DAC) for analog output generation. For instance, high-resolution 16-bit or 18-bit ADCs sample the input at rates exceeding twice the signal bandwidth to satisfy the Nyquist criterion, while DSPs or FPGAs handle the computational load in real time.^[18]^[19]^[6] Reference signal handling in digital implementations relies on direct digital synthesis (DDS) to generate precise sine and cosine waveforms numerically, enabling low phase noise and rapid phase locking without physical oscillators. This method supports reference frequencies from millihertz up to 8.5 GHz in advanced models suited for microwave applications, far surpassing typical analog limits. DDS uses lookup tables or algorithmic generation to produce orthogonal in-phase (I) and quadrature (Q) components for demodulation, with support for internal, external, or dual-reference modes to accommodate diverse experimental setups.^[6]^[18]^[19] The primary processing steps involve digital multiplication of the digitized input with the I and Q reference signals—a technique known as IQ demodulation—to extract amplitude and phase information. This is followed by low-pass filtering using finite impulse response (FIR) or infinite impulse response (IIR) filters, often with selectable roll-off rates such as 6, 12, or 24 dB/octave and time constants ranging from microseconds to seconds, to suppress noise and the second-harmonic component at 2ω. Modern designs support multiple channels and demodulators, allowing simultaneous processing of several signals or harmonics (up to the 99th order) through parallel FPGA pipelines, which enable efficient handling of complex, multi-frequency measurements.^[6]^[18]^[19] Additional features enhance usability and integration in laboratory environments, including real-time fast Fourier transform (FFT) for spectral analysis of inputs or filtered outputs, proportional-integral-derivative (PID) control loops for feedback stabilization, and onboard data logging with buffers up to 32,000 points at 16-bit resolution. Software interfaces, such as those compatible with LabVIEW, MATLAB, Python, or custom APIs via GPIB, RS-232, USB, or Ethernet, facilitate automated control and data acquisition. These elements were pioneered in the mid-1980s with the advent of early DSP chips, which replaced analog multipliers, and have since advanced to FPGA-based systems for parallel harmonic processing and higher throughput.^[6]^[19]^[18]^[15]

Advantages Over Analog

Digital lock-in amplifiers offer a superior frequency range compared to their analog counterparts, extending from DC up to several gigahertz, such as 1.8 GHz in models like the Zurich Instruments GHFLI, enabled by high-speed digital sampling and processing that overcomes the component limitations of analog designs, which typically cap at hundreds of kilohertz or low megahertz for standard implementations.^[20]^[8] They provide enhanced stability by eliminating drift inherent in analog components like resistors and capacitors, and no DC output offsets through precise digital signal processing. Programmable phase and gain settings further improve precision, with phase resolutions down to 0.001° possible in devices such as the Stanford Research Systems SR850.^[8]^[21] In terms of noise performance, digital lock-in amplifiers feature a lower inherent noise floor, often around 3.5 nV/√Hz, and excel at rejecting 1/f noise through advanced digital filtering techniques that maintain effective bandwidth narrowing without analog imperfections. This results in a higher dynamic range, exceeding 100 dB of drift-free reserve, allowing reliable extraction of weak signals buried in noise levels unattainable with analog systems limited to about 60 dB.^[6]^[8] Digital implementations enhance flexibility by supporting simultaneous demodulation at multiple frequencies and harmonic analysis without signal-to-noise ratio losses from channel splitting, as well as seamless integration with lock-in-based controllers via software interfaces. Since the 2000s, they have reduced setup times through automated gain, phase, and offset adjustments, enabled remote control over networks, and become cost-effective for multi-channel configurations by leveraging scalable digital signal processors rather than multiple analog units.^[6]^[22] Although digital lock-in amplifiers may involve higher initial costs and require more computing power for real-time processing, these drawbacks are offset by their longevity, reduced maintenance, and overall performance gains in modern laboratory environments.^[23]

Noise Reduction Techniques

Signal Modulation Methods

Signal modulation methods in lock-in amplifiers prepare the signal of interest by converting it from DC or low-frequency AC to a higher-frequency AC form at a known reference frequency, thereby shifting it away from dominant low-frequency noise sources such as 1/f noise.^[24]^[25] This modulation enables subsequent phase-sensitive detection to isolate the desired signal with high sensitivity. The modulation frequency is typically selected above the noise knee of the system, often greater than 100 Hz, to minimize contributions from thermal noise and 1/f fluctuations while staying below frequencies where other noise sources, like shot noise, might dominate.^[26] External modulation employs mechanical devices, such as chopper wheels, to periodically interrupt the signal path and convert DC signals to AC at reference frequencies ranging from 1 to 10 kHz, commonly used in optical and spectroscopic setups.^[26]^[27] A chopper wheel consists of a rotating disk with evenly spaced slots that block and pass the signal, achieving a 50% duty cycle to approximate square-wave modulation synchronous with the reference.^[28] This method was historically pivotal in 1950s infrared spectroscopy, where mechanical choppers modulated IR sources to enable weak signal detection amid background noise.^[29] Internal modulation, in contrast, uses electrical techniques to directly vary the sensor or source drive signal, such as through voltage-controlled oscillators applied to photo-detectors or bias voltages in sensing elements.^[30]^[31] In non-dispersive infrared (NDIR) gas sensors, for example, the IR source is electrically modulated at the reference frequency, allowing lock-in detection to extract gas absorption signals while rejecting ambient noise.^[32]^[33] This approach avoids mechanical components, offering greater stability and suitability for compact or high-frequency applications.

Phase-Sensitive Detection Process

The phase-sensitive detection process in a lock-in amplifier involves multiplying the modulated input signal by a reference signal that is phase-locked to the modulation frequency, thereby extracting the coherent signal component while producing sum and difference frequency terms. The low-pass filter following multiplication integrates the product over time, retaining only the DC component, which is proportional to the input signal amplitude and the cosine of the phase difference between the input and reference.^[8] This process requires prior signal modulation to shift the desired component to a higher frequency away from low-frequency noise.^[34] Uncorrelated noise, lacking phase coherence with the reference, results in a product that averages to zero during integration, effectively rejecting broadband noise outside the narrow detection bandwidth. The equivalent noise bandwidth of the post-multiplication low-pass filter is given by \Delta f = \frac{1}{4\tau}, where \tau is the filter time constant, determining the trade-off between noise reduction and measurement speed.^[8] DC offsets and drifts in the input or multiplier stages are mitigated through DC blocking capacitors in the signal path and auto-zeroing techniques in the preamplifier, preventing contamination of the DC output.^[35] In dual-phase detection, the reference is demodulated separately using in-phase (0°) and quadrature (90°-shifted) components, yielding X and Y outputs that represent the vector projections of the signal. The signal magnitude is then \sqrt{X^2 + Y^2} and the phase \arctan(Y/X), allowing full characterization independent of relative phase.^[6] This detection enhances the signal-to-noise ratio (SNR) proportionally to \sqrt{\tau}, as longer integration reduces output noise variance. Typical time constants range from 10 ms to 10 s, enabling noise floors below 3 nV/√Hz in high-performance systems.^[8]^[20] For non-sinusoidal signals, harmonic detection employs reference frequencies at integer multiples (e.g., 2f or 3f) of the fundamental, isolating higher-order components from nonlinear responses while maintaining phase sensitivity.^[35]

Applications

Physics and Chemistry

In atomic force microscopy (AFM), lock-in amplifiers enable nanoscale force detection by extracting weak oscillatory signals from the cantilever, which is driven at resonance frequencies typically in the kHz range to achieve sub-angstrom resolution in surface topography and material property mapping.^[36]^[37] This technique has been integral to scanning probe technologies since the 1980s, allowing precise measurements of atomic-scale interactions in dynamic modes like frequency-modulation AFM.^[38] Lock-in detection enhances sensitivity to amplitude and phase variations, facilitating applications in nanoscale imaging under noisy conditions.^[39] Photoacoustic spectroscopy employs lock-in amplifiers to analyze material properties by detecting acoustic waves generated from modulated light absorption, providing insights into thermal and optical characteristics of samples.^[40] The amplifier synchronizes with the modulation frequency of the excitation source, isolating the photoacoustic signal from environmental noise and enabling quantitative assessment of absorption spectra in solids, liquids, and gases.^[41] This approach is particularly valuable for non-destructive evaluation of thin films and biological tissues, where signal amplitudes are often in the microvolt range.^[42] In low-temperature physics, lock-in amplifiers facilitate Hall effect measurements in semiconductors under applied magnetic fields, allowing precise determination of carrier density and mobility at cryogenic temperatures down to millikelvin regimes.^[43] By using AC magnetic fields and phase-sensitive detection, the technique suppresses offset voltages and thermal noise, yielding accurate Hall voltage readings in the microvolt to nanovolt range for materials like graphene and high-temperature superconductors.^[44] These measurements are essential for studying quantum transport phenomena, such as the quantum Hall effect, in controlled low-noise environments.^[45] Quantum optics experiments utilize lock-in amplifiers for detecting weak photon signals in entanglement studies, where they demodulate time-correlated or modulated optical outputs to verify quantum correlations amid broadband noise.^[46] In setups involving photon pair generation and interference, the amplifier locks to chopper-modulated references, enabling high-fidelity extraction of coincidence counts and phase information for entangled states at wavelengths like 2.1 μm.^[47] This enhances the signal-to-noise ratio in protocols for quantum key distribution and Bell inequality tests, supporting entanglement verification with minimal dark counts.^[48] In chemistry, electrochemical impedance spectroscopy (EIS) relies on lock-in amplifiers to probe reaction kinetics by applying a small AC perturbation and measuring the frequency-dependent impedance of electrochemical cells.^[49] The phase-sensitive detection isolates in-phase and quadrature components, revealing charge transfer resistances and double-layer capacitances for processes like corrosion or battery operation, with sensitivities down to 1 mHz.^[50] This method quantifies kinetic parameters without DC bias interference, aiding in the study of interfacial reactions in solutions and solid-state systems.^[51] Fluorescence lifetime measurements in chemical analysis use lock-in amplifiers in phase-modulation schemes to determine excited-state decay times from nanoseconds to microseconds, correlating with molecular environments and quenching effects.^[52] By modulating the excitation light and detecting the phase shift of the emitted fluorescence, the technique achieves high temporal resolution with low-cost setups operating up to 200 MHz, suitable for characterizing fluorophores in biological and material samples.^[53] Outputs from dual-phase lock-ins provide demodulation ratios and phase angles for accurate lifetime extraction, enhancing specificity in time-resolved spectroscopy.^[54] Non-dispersive infrared (NDIR) sensors for gas detection, such as CO₂ monitoring at parts-per-million levels, incorporate lock-in amplifiers to demodulate modulated IR absorption signals, improving selectivity and sensitivity in ambient air analysis.^[55] The technique uses a reference signal synchronized to the IR source chopper, enabling detection limits as low as 50 ppm for CO₂ via differential pathlength measurements in compact, low-cost systems.^[56] This approach minimizes cross-interference from humidity and other gases, supporting applications in environmental monitoring and breath analysis.^[57]

Engineering and Industry

In mechanical engineering, lock-in amplifiers are employed for vibration analysis in systems such as gears and rotating machinery, where they enable precise detection of faults by extracting periodic signals from noisy environments.^[58] For instance, in gear diagnosis, the technique processes vibration data to identify anomalies like cracks or wear without requiring extensive signal preprocessing.^[58] Additionally, lock-in amplifiers integrate with proportional-integral-derivative (PID) controllers in feedback systems, providing stable phase-sensitive measurements for real-time stabilization in applications like distributed fiber optic sensing.^[59] This integration enhances control precision by mitigating noise in the feedback loop, as demonstrated in electro-optic modulator bias voltage stabilization. In industrial non-destructive testing (NDT), lock-in amplifiers facilitate eddy current inspection to detect flaws in metallic structures, such as cracks or corrosion, by demodulating induced currents at specific frequencies.^[60] These devices act as narrowband filters to isolate defect signals from background noise, improving detection sensitivity in conductive materials used in aerospace and manufacturing.^[61] Lock-in amplifiers enhance sensor technology by processing outputs from accelerometers and strain gauges in harsh environments, including oil rigs, where they recover weak vibration signals amid electromagnetic interference and mechanical noise.^[62] This capability supports structural health monitoring in offshore platforms, ensuring reliable data from sensors exposed to extreme temperatures and vibrations.^[62] In telecommunications, lock-in amplifiers aid signal recovery in fiber optic systems by extracting weak modulated light signals from noise, particularly in long-distance transmission where attenuation degrades performance. They are integrated into Brillouin scattering-based sensors for distributed monitoring along optical fibers, enabling precise phase and amplitude detection. In NDT applications like eddy current testing, lock-in amplifiers process signals up to several MHz for high-resolution defect imaging, with commercial systems from Zurich Instruments—available since the mid-2000s—incorporating automation features for efficient industrial workflows.^[63] Emerging applications include integration of digital lock-in amplifiers into Internet of Things (IoT) sensors for environmental monitoring, where their low-power designs enable battery-operated detection of parameters like gas concentrations in remote or resource-constrained settings.^[64] Digital implementations offer scalability for such deployments by minimizing power consumption while maintaining high signal fidelity.^[64]

References

[1]
[PDF] About Lock-In Amplifiers - thinkSRS.com
Lock-in amplifiers are used to detect and measure very small. AC signals all the way down to a few nanovolts. Accurate measurements may be made even when ...
[2]
[PDF] What is a Lock-In Amplifier - Advanced Labs
It is a very powerful instrument where signals of interest can be detected even if they are smaller than the noise signals they accompany (see fig. 1).
[3]
[PDF] What is a Lock-in Amplifier?
Page 1. In its most basic form a lock-in amplifier is an instrument with dual capability. It can recover signals in the presence of an overwhelming noise ...
[4]
[PDF] Lec 14: Lock-in amplification
to Robert Dicke while at MIT. First commercial lock-in amplifier: Princeton Applied Research (1962). Modern digital signal processing has greatly improved ...
[5]
Principles of Lock-in Detection | Zurich Instruments
A lock-in amplifier performs a multiplication of its input with a reference ... [4] Interview of Robert Dicke by Martin Hawrit.Niels Bohr Library and ...
[6]
https://www.zhinst.com/en/resources/principles-of-lock-in-detection
[7]
[PDF] About Lock-In Amplifiers - thinkSRS.com
A lock-in amplifier, because it multiplies the signal with a pure sine wave, measures the single Fourier (sine) component of the signal at the reference ...
[8]
[PDF] Principles of lock-in detection and the state of the art
Nov 21, 2016 · Lock-in amplifiers were invented in the 1930's [1, 2, 3] and commercialized [4] in the mid 20th century as electrical ...
[9]
An Improved Synchronous Detector - AIP Publishing
The synchronous amplifier design of Michels and Curtis has been modified to minimize feedback and so to allow preamplification and high sensitivity.
[10]
Robert H. Dicke, 1916-1997 | Department of Physics
... lock-in amplifier." With its successors this probably has contributed as ... He is survived by Annie and their children Nancy Dicke Rapoport, John Robert Dicke, ...
[11]
[PDF] The Analog Lock-in Amplifier - AMETEK Scientific Instruments
For many years the lock-in amplifier was an all-analog instrument. As technology developed, digital electronics, in the form of.
[12]
Princeton Applied Research | Potentiostat
With a desire to establish significant improvements to research instrumentation the team developed the first commercial lock-in amplifier in 1962. After ...Missing: 1960 | Show results with:1960
[13]
Design a DSP lock-in amplifier, Part 2: Design methodology - EDN
Dec 27, 2017 · Here, I'll cover analog and digital lock-in amplifiers, software-defined radio, de-embedding, and the hardware and software architecture of the design.
[14]
A low-cost, high-performance, digital signal processor-based lock-in ...
Jan 20, 2005 · This lock in is capable of measuring simultaneously multiple frequencies that change in time as frequency sweeps (chirps).
[15]
[PDF] Signal-to-noise ratio in lock-in amplifier synchronous detection
In this review article, a generalized communications sys- tems approach to signal and noise processing by the basic circuit of two-phase lock-in amplifiers has ...
[16]
[PDF] The Digital Lock-in Amplifier - AMETEK Scientific Instruments
A digital lock-in amplifier uses digital signal processing for phase-sensitive detection, offering advantages over analog units, such as better output ...
[17]
[PDF] Lock-In Amplifiers - Acal BFi
Microprocessor based designs emerged in the 1980s, and by the early 1990s even the lock-in's analog demodulators were replaced by high-resolution ADCs and.
[18]
Understanding the Specifications of Lock-in Amplifiers
Feb 20, 2023 · Depending on the instrument, Zurich Instruments' lock-in amplifiers can achieve demodulation bandwidths ranging from 300 uHz up to 11 MHz. ...
[19]
SR850 - Lock In Amplifier - thinkSRS.com
0.001 degree phase resolution; Time constants from 10 µs to 30 ks (up to 24 dB/oct rolloff); Auto-gain, phase, reserve and offset; Data logging (up to 65k ...
[20]
(PDF) Development and Test of Low-Cost Multi-Channel Multi ...
Sep 13, 2024 · In this paper, we describe a new fully-digital low-frequency lock-in amplifier developed at ENEA C.R. Frascati Laboratories for ...
[21]
Lock-in Amplifier - an overview | ScienceDirect Topics
A lock-in amplifier (LIA) is defined as an electronic device used to demodulate signals, particularly in applications involving laser scanning microscopy, ...
[22]
Understanding and Eliminating 1/f Noise - Analog Devices
1/f noise can limit performance in any precision dc signal chain. However, it can be removed by using techniques such as chopping and ac excitation. There are ...
[23]
Removing 1/f noise with lock-in-amplifiers - Physics Stack Exchange
Nov 22, 2021 · One method of removing this is to modulate the signal at some higher frequency and use a lock-in-amplifier to detect the now modulated signal synchronously.
[24]
[PDF] Low Level Optical Detection using Lock-in Amplifier Techniques
Most modern lock-in amplifiers incorporate an internal oscillator, the output of which can be connected to the chopper's reference frequency input. If this is ...
[25]
Optical Choppers - RP Photonics
The lock-in amplifier can then very sensitively detect that modulation and can, if required, also determine its phase. Particularly good signal-to-noise ratios ...
[26]
A Lock-In Amplifier - Circuit Cellar
Nov 4, 2023 · Lock-in amplifiers are primarily designed to measure low-level signals in the presence of noise/interference that is generally much higher in amplitude than ...Missing: hardware | Show results with:hardware
[27]
[PDF] Model SR844 RF Lock-In Amplifier - thinkSRS.com
Lock-in amplifiers as a general rule measure the input signal in Volts rms. ... signal by the lock-in reference, which is really a square wave. A ...
[28]
[PDF] Instrumentation for Far-infrared Spectroscopy
In the late 1950s and early 1960s, two manufacturers intro- duced double ... demodulated with a lock-in amplifier. The instrument was equipped with a ...
[29]
Study of measuring the intensity distribution of LED with lock-in ...
Oct 11, 2010 · ... internal modulation. The structure of the research system, the transmitter module, the optical receiving module, the research light path and ...
[30]
https://www.spiedigitallibrary.org/conference-proceedings-of-spie/7656/765622/Study-of-measuring-the-intensity-distribution-of-LED-with-lock/10.1117/12.863727.full
[31]
Development and Measurements of a Mid-Infrared Multi-Gas Sensor ...
The light source modulation signal is used as a reference signal for the lock-in amplifier. The lock-in amplifier will produce a square wave which has the same ...
[32]
Non-dispersive infrared multi-gas sensing via nanoantenna ... - Nature
Oct 16, 2020 · Non-dispersive infrared (NDIR) spectroscopy analyzes the concentration of target gases based on their characteristic infrared absorption.
[33]
[PDF] The Phase Sensitive (Lock-in) Detector
The “lock-in amplifier” is an instrument used in many physics experiments because of its special effectiveness in reducing noise in electrical measurements.
[34]
[PDF] The Lock-In : Noise Reduction and Phase Sensitive Detection
The two essential reasons for using a Lock-In amplifier in a scientific experiment are its ability to. „reduce noise“, i.e. to improve the Signal-to-Noise ...
[35]
Atomic Force Microscopy - Nanoscience Instruments
HD KFM requires a second lock-in amplifier as shown below. Because the single pass does not require tip to “lift” above the surface, resolution of the ...Contact Modes For Afm · Dynamic Modes For Afm · Electrical Modes For Afm
[36]
An Analog High-Speed Single-Cycle Lock-in Amplifier for Next ...
In this paper, we present a new architecture for analog amplitude demodulation in high-speed atomic force microscopy (AFM) applications.
[37]
Customization of an atomic force microscope for multidimensional ...
Jun 26, 2023 · The FM-AFM has been enabled by the lock-in amplifier with phase-locked loop (PLL) capability while experiment customization and automation have ...
[38]
Measurement and Control System for Atomic Force Microscope ...
Jan 15, 2023 · The lock-in amplifier is used to detect a weak signal. It uses a reference signal with the same frequency as the measured signal as a basis for ...
[39]
Sound of Light - Lock-in Amplifiers Applications in Photoacoustic ...
Dec 20, 2022 · In photoacoustic spectroscopy, the signal collected from the microphone needs to be amplified by a preamplifier and then locked to the frequency ...
[40]
[PDF] Structure of Photoacoustic Spectroscopy (PAS) Cells and Lock-in ...
In this study, photoacoustic spectroscopy (PAS) cells and lock-in amplifiers (LIAs) were surveyed to develop PAS gas sensors. PAS.
[41]
Lock-in detection of photoacoustic feedback signal for focusing ...
Nov 23, 2016 · A lock in amplifier detects the modulated PA signal and its output is used as a feedback for the SLM optimization. Focusing through the ...
[42]
Hall effect measurements using low ac magnetic fields and lock-in ...
Jan 31, 2020 · Here, we report the results of the Hall effect measurements using ac magnetic fields and a lock-in detection of the Hall voltage for field ...
[43]
Hall voltage measurements using ac lock-in detection - ResearchGate
Aug 6, 2025 · A simple electronic circuit using commercial lock‐in amplifiers is described which allows measuring these minute Hall voltages.
[44]
Revealing contributions to conduction from transport within ordered ...
Mar 30, 2023 · For the Hall measurements, the voltage signal was extracted by use of a Stanford Research Systems SR830 lock-in amplifier via a SR551 voltage ...
[45]
Two-photon quantum interference and entanglement at 2.1 μm
Mar 27, 2020 · To enhance the signal-to-noise ratio, we used an optical chopper and a lock-in amplifier to detect the generated signal. Characterization of ...
[46]
Quantum lock-in measurement of weak alternating signals
Feb 26, 2024 · Lock-in measurement can be used to efficiently extract a weak alternating signals with high SNR from an extremely noisy environment.
[47]
Entanglement-enhanced quantum metrology: From standard ...
Jul 2, 2024 · This article aims to review and illustrate the fundamental principles and experimental progresses that demonstrate multi-particle entanglement for quantum ...<|separator|>
[48]
Hands-on Electrochemical Impedance Spectroscopy
Jun 28, 2022 · The MFLI Lock-in Amplifier is an instrument with a reference signal output and a measurement input. Those can be correlated. So, in principle, ...
[49]
Fast lock-in amplifier electrochemical impedance spectroscopy for ...
This paper suggests a Fast Lock-in Amplifier (FLA). It takes place of low pass filter with linear average definite digital Integrator.
[50]
Electrochemical Impedance Spectroscopy (EIS) - Gantner Instruments
Apr 18, 2024 · Phase-Sensitive Output: The Lock-in amplifier produces an output proportional to the cosine of the phase difference between the reference signal ...
[51]
Low cost phase-modulation measurements of nanosecond ...
Feb 1, 1999 · The use of a 200 MHz lock-in amplifier was demonstrated as a low cost instrument for frequency domain measurements of nanosecond fluorescence lifetimes.
[52]
Low-cost phase-modulation fluorometer for measuring nanosecond ...
A Stanford Research Systems SR844 lock-in amplifier was used to build a sub $10,000 phase-modulation fluorometer capable of measuring nanosecond ...<|separator|>
[53]
Directed Evolution of Excited State Lifetime and Brightness in ... - NIH
The lock-in amplifier outputs in-phase and quadrature phase signals that are used for frequency-domain measurements of the excited state lifetime of theRFP ...
[54]
[PDF] Development of a Low-cost NDIR System for ppm Detection of ...
A lock-in amplifier has been developed to extract the response to CO2, based on a drive signal from the IR source. The frequency extraction process enabled a ...Missing: modulation | Show results with:modulation
[55]
(PDF) Development of a Low-cost NDIR System for ppm Detection of ...
Aug 6, 2025 · A lock-in amplifier design permits a CO2 concentration of 50ppm to be detected on gas bench rig. Different IR path lengths were studied with ...<|control11|><|separator|>
[56]
A low cost MEMS based NDIR system for the monitoring of carbon ...
MEMS based NDIR system for ppm CO 2 detection with lock-in amplifier. Fast 1.3s response time for breath-by-breath analysis.
[57]
Application of Lock-In Amplifier on gear diagnosis - ScienceDirect.com
In this work, the use of Lock-In Amplifier (LIA), which leads to a time analysis approach, is proposed to be applied on gear fault detection.
[58]
Top 10 Tips for Optimizing Your PID Controller | Zurich Instruments
Feb 26, 2025 · We share a compact compilation of ten tips to help you make the best out of the PID controllers on Zurich Instruments lock-in amplifiers.
[59]
Design of a lock-in amplifier integrated with a coil system for eddy ...
Eddy-current non-destructive inspections of conductive components are of great interest in several industries including civil infrastructure and the mining ...
[60]
Eddy Current Rail Inspection Using AC Bridge Techniques - PMC
The lock-in amplifier can act as a very narrow band pass filter (BPF) array which can extract the defect signal based only on the specific excitation reference ...
[61]
(PDF) Digital Lock-In Amplifier Technology for Harsh Environments
This paper reviews the research progress of digital lock-in amplifier (DLIA) in the field of mechanical engineering, and discusses the advantages and challenges ...
[62]
Eddy Current Testing with the MFLI Lock-in Amplifier
Aug 5, 2015 · This blog post describes a method to detect material defects. Eddy current measurements are used for non-destructive material testing (NDT).
[63]
An Integrated Low-Power Lock-In Amplifier and Its Application to ...
This paper presents a new micropower analog lock-in amplifier (LIA) suitable for battery-operated applications thanks to its reduced size and power consumption ...