Lock-in amplifiers use PSD (Phase Sensitive Detector), a phase-sensitive detecting technology. Only signals at a specific reference frequency can be selected. Noise and interference signals at other frequencies are not detected. It is a highly sensitive data acquisition device for detecting very weak AC signals. Accurate measurement can be ensured even when the noise is several thousand times stronger than the signal.
Traditional lock-in amplifiers use analog frequency mixers and RC filters for the demodulation. Complicated analog circuit designs and optimization for analog signal demodulation are indispensable. Today, lock-in amplifiers have been transformed to adopt advanced integrated circuit technology and fast digital signal processing (DSP), increasing their sensitivity and reliability by hundreds of times.
Customer cases:
2. A Prototype of High-Precision Carbon Isotopic Ratio Sensing System for CO₂ Dissolved in Water
HealthyPhoton's mini lock-in demodulation board is designed with the state-of-art configuration of an FPGA plus an ARM microcontroller. The floating-point signal processing is completed and optimized by FPGA hardware acceleration. The result data acquisition and host computer interaction are handled by an ARM MCU. To improve the cost performance, the system is designed for independent dual I/O channel, so that dual lock-in demodulation channel is realized on a single board, plus additional dual-channel DDS signal generations. For example, one channel can be used as a signal, and the other as a reference. Alternatively, one channel can be used for the 1st harmonic demodulation, and the other is for the 2nd harmonic demodulation.
The dual low-noise ADC samples the analog signal and converts it into two separate digital data streams, followed by the FPGA calculations. The FPGA result is sent to the ARM microcontroller for further low-speed signal processing and then sent to the host computer via the serial communication port. Note that the lock-in demodulation results can also be converted directly to the analog signal output through auxiliary DACs (AUX_DACs). Moreover, a dual-channel Direct Digital Synthesizer (DDS) is used to generate two independent analog signals to two high-speed DACs that externally modulate lasers or other transmitters. All the lock-in and modulation parameters are set via a user interface installed on a PC.
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Overall |
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Dimension |
15.4x15.4x7.6cm3 |
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Weight |
670g |
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Power supply |
DC 5V/2A |
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Analog input |
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Frequency |
AC ~ 0.5MHz |
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Input resistance |
50 ohm |
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Input noise |
10nV/Hz1/2 (>10 kHz) |
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Voltage |
-1V to +1V |
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ADC |
14 bit; 4 MSa/s |
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DDS analog output |
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Output |
2 channels; -1V to +1V |
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Frequency |
DC ~ 0.5MHz |
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DAC |
16 bit; 4 MSa/s |
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Lock-in demodulator |
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Number of demodulators |
2 |
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Time constant |
10ms, 100ms (can be customized) |
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Filter bandwidth (Hz) |
1000, 100 (can be customized) |
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Harmonic |
1F, 2F, 3F, 4F |
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Reference phase resolution |
1.0 degree |
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Auxiliary output (AUX_DAC) |
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Output channels |
2 channels; -10V to +10V |
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DAC |
16 bit; 4 Msa/s |
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DAC analog bandwidth |
10 kHz |
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Host port |
USB virtual serial port |
Tel:+86-156-1892-2826 Email:info@healthyphoton.com
Add:Room 305, Building 1, Zhongchuang Science Park, Jinyuan Road, Panhuo Street, Yinzhou District, Ningbo City,China
