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OE2031 Digital Lock-In Amplifiers
    Now OE2031 DSP Lock-In Amplifier is the newest product of core technology with high performance. Based on the digital demodulation, output filter and high-precision stabilized 16-bit ADC, it is ideal to detect the weak signals, which are overwhelmed by greatly larger noise components. And OE2031 could measure the magnitude and phase of a signal simultaneously. It could be comparable with the international leading technology in some core parameters, like accuracy of measurement, range of operating frequency, SNR, dynamic reserve and so on. Meanwhile, we have integrated other functions like multiple-harmonic measurement in OE2031, which makes this DSP Lock-In Amplifier could meet the needs of scientific research and industrial purposes.
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OE2031 Digital Lock-In Amplifiers


Overview

Now OE2031 DSP Lock-In Amplifier is the newest product of core technology with high performance. Based on the digital demodulation, output filter and high-precision stabilized 16-bit ADC, it is ideal to detect the weak signals, which are overwhelmed by greatly larger noise components. And OE2031 could measure the magnitude and phase of a signal simultaneously. It could be comparable with the international leading technology in some core parameters, like accuracy of measurement, range of operating frequency, SNR, dynamic reserve and so on. Meanwhile, we have integrated other functions like multiple-harmonic measurement in OE2031, which makes this DSP Lock-In Amplifier could meet the needs of scientific research and industrial purposes.


Input Channel
With the low-noise analog pre-amplifier, the signal input of OE2031 can be switched to operate in the single-ended or differential voltage mode, and the input noise is 10 nV/√Hz. The input impedance is 10 MΩ and the full-scale input voltage sensitivity ranges from 1 nV to 1 V. Besides, OE2031 can also be used for current measurements with variable current gains of 10 or 10 V/A. Two line filters (50/60 Hz and 100/120 Hz) are designed to eliminate line related interference. The programmable gain amplifier is provided to adjust the dynamic reserve of the system according to the magnitude of the input signal, so that OE2031 has inherently large dynamic reserve up to 80 dB. The sampling rate of 10MSPS is determined by a precision 16-bit A/D converter and a specific filter is designed to avoid aliasing.


Reference Channel
In order to provide the reference signal for OE2031, an externally applied sine wave or square wave, or its own internally synthesized reference source could be used. When the instrument is set to internal reference mode, the internal precision stabilized oscillator and the digital synthesized algorithm are used to generate sinewave output that multiplies the input signal, there is virtually no reference phase noise when choosing internal reference mode. Taking advantage of digital phase-shifting technique, the reference signal phase could be adjusted with 0.01° resolution. The internal reference mode can operate at a fixed frequency from 1 mHz to 3MHz. In addition, the external reference is also applicable to OE2031, including the sinewave reference signal and TTL logic reference signal. The rising and trailing edge of external reference signal are applied to trigger off the internal PLL (Phase Locked Loop). Based on the frequency of reference signal, harmonic detection can be performed by OE2031. The maximum frequency of the measurable harmonics is 32767 times of basic frequency, and it is also less than the maximum
operational frequency 3 MHz.

Digital Demodulator and Output Filter
The core of Lock-In Amplifier OE2031 is demodulator. This digital demodulator could be effectively immune from the potential errors caused by DC drift and offset found in analog multipliers or switches. The coherent signal multiplication has been optimized for very low calculation error. The time constants of OE2031 could be configured extending from 10 µs to 30 ks. The roll-offs of the output low-pass filter on OE2031 are 6, 12, 18 and 24 dB/octave. This low-pass filter is carried out by the architecture of digital infinite impulse response (IIR) filters and updated at 10 MHz signal sampling rate. The advantages of this design over common analog instruments are higher dynamic reserve (>80 dB), accurate phase shifts (absolute phase error <1°), zero drift, and orthogonality. Meanwhile, below 200 Hz, OE2031 can perform synchronous filtering, which is used to notch out multiples of the reference frequency. This function ensures that OE2031 works quickly at low frequency.

Display
OE2031 uses the 5.6 inch 640×480 TFT color display as its screen. Data measured by OE2031, such as, X, Y, R, θ, is stored in up to four traces. Trace values can be displayed as a bar graph or as a strip chart showing the trace values as a function of time.
                                                  

OE2031 can also show the relationship of time and range in a XY graph and you can check the value of sampling point by using knob control cursor.

                                                   

Besides, OE2031 can display polar plots, showing phasor composed by in-phase and quadrature components of the signal. All displays can be easily scaled by the manual operation, and the auto-scale feature is available to optimize display quickly. The screen can be configured as a single large display, or two horizontally-split displays.

                                                     

Simultaneous Multiple-harmonic Measurement
The traditional phase-locked amplifier can only measure fundamental frequency signal or one certain harmonic ware at the same time, so it can not meet the requirement in some occasions when measuring multiple frequency components simultaneously is needed. In digital end, OE2031 combined FPGA and ARM technology, which has wider processing bandwidth and more flexible digital framework. The digital processing precision could reach 54 bits and could measure 3-channal harmonic components simultaneously, which makes one OE2031 is equal to three traditional phase-locked amplifiers.

                                                      

Internal Oscillator
The internal oscillator helps to generate a very low distortion (–80 dBc) reference signal. The single frequency of sine waves can be extended from 1 mHz to 3 MHz while the resolution generated is 0.1 mHz. Both frequency and amplitude can be set from the front panel or a computer. When choosing external reference mode, the internal oscillator is phase-locked to the external reference signal.


Signal Generator
OE2031 generates one sinusoidal signal in range from 1 mHz to 3 MHz, using 16-bit D/A converter. The frequency and phase shift of this sinusoidal signal are corresponding to that of the internal reference signal, and its amplitude could be set with control menu. The maximum amplitude provided by signal generator is 10 Vpp.


Manual Operation
In addition to displaying data, the color TFT display panel is also used to display the control menu. In conjunction with keys grouped around the screen and numeric keypad, customers could adjust instrument's parameters effectively, such as oscillator frequency, which can be set to a fixed value and to a high precision.

Auto Function
OE2031 has the ability to adjust measurement parameters to optimum setting for input signal. Gain, phase, dynamic reserve and display scaling could all be set with different independent key presses from the control menu. With this function, the input signals could be measured easily and automatically.


Interface
OE2031 regards RS-232 to USB interfaces as standard. And, all instrument functions can be controlled and read through USB interfaces. To debug conveniently, all of the interfaces could be viewed on front panel. For convenient debugging, characters received and sent via interfaces can be viewed on front panel.


Remote Operation
The built-in RS232 to USB interfaces on OE2031 allow full manual operation from a controlling computer, including setting or interrogating control and reading out data. Free LabVIEW program is provided. It makes it easy to set up and run complex experiments, such as remote control of every instrument function. The display menu offered by the LabVIEW program allows customers observe all command received and responses generated by instrument
                   



Signal Channel
Voltage input Mode  Single-ended or Differential
Full-scale Sensitivity 1nV to 1 V in a 1-2-5 sequence
6 8
Current input  10 or 10 V/A
Impedance
Voltage  10 MΩ // 25pF, AC or DC coupled
Current  1kΩ to virtual ground
C.M.R.R  >80 dB to 10 KHz, decreasing by 6 dB/oct
Dynamic reserve >80 dB
Gain accuracy  0.2% typ, 1% max
Noise 10nV/√Hz at 1 kHz
0.13pA/√Hz at 1 kHz
0.013pA/√Hz at 100 Hz
Line filters 50/60 Hz and 100/120 Hz

Gounding BNC shield can be grounded or floated via 1kΩ to ground


Reference Channel
Input
Frequency range 1 mHz to 3 MHZ
Reference input TTL or sine
Input impedance 1 MΩ//25 pF
Phase
Resolution 0.01° increments
Absolute phase error  <1°
Relative phase error  <0.01°
Orthogonality  90°±0.001°
Phase noise
Internal ref. Synthesized, <0.0001°rms at 1kHz
External ref.  0.005°rms at 1 kHz (100 ms time constant, 12 dB/oct)
Drift <0.01°/℃ below 10 kHz
<0.1°/℃ above 10 kHz
Harmonic detection  2F, 3F, …nF to 3 MHZ (n<32,767)
Acquisition time
Internal Ref.  Instantaneous acquisition
External Ref.  (2 cycles + 5 ms) or 40 ms, whichever is larger


Demodulator
Stability
Digital outputs  no zero drift on all setting
Display no zero drift on all setting
Analog outputs <5 ppm/℃ for all dynamic reserve settings
Harmonic rejection  -90 dB
Time constants 10µs to 3ks (<200Hz)
10µs to 30s (>200Hz)
(6, 12, 18, 24 dB/oct rolloff)
Synchronous filters  Available below 200 Hz


Internal Oscillator
Frequency
Range  1 mHz to 3MHz
Accuracy 25 ppm + 30 µHz
Resolution 1 mHz, whichever is greater
Distortion -80 dBc (f<10 kHz),
-70 dBc (f>10 kHz)
Amplitude 0.001 to 10 Vpp
Accuracy 1%
Stability  50 ppm/℃
Outputs  Sine, 50 Ω output impedance


Display
Screen  5.6 inch, 640×480 TFT
Screen format  Single or dual display
Display quantities  Each display shows one trace,
traces can be defined as X,Y,R,θ
Display types  Large numeric readout, bar graph, polar plot and strip chart


Outputs
CH1 and CH2 Outputs
Function  X, Y, R, θ
Amplitude ±10 V
Impedance 100 Ω


Interfaces
RS-232 to USB interfaces. All instrument functions can be controlled and read through USB interfaces.


General
Power requirements
Voltage  220/240V AC
Frequency 50/60 Hz
Power  40 W
Dimensions
Width  473 mm
Depth  490 mm
Height
With feet 160 mm
Without feet  147 mm
Weight  12 KG