The invention relates to a lock-in amplifier, and in particular to the integration of a phase-synchronous processing (PSP) unit in a lock-in amplifier.
Lock-in Amplification:
Lock-in amplification is a widely used technique to recover a signal of interest. It is a particular type of demodulation with specific requirements to the filter performance and flexibility in setting the demodulation frequency. Demodulation is performed on the measured signal in order to obtain the phase and the amplitude of the signal of interest at a specific frequency. Lock-in amplification is equally used to narrow band signal and wide band signal analysis.
In a digital lock-in amplifier, all calculations are carried out with digital numbers in a virtually error-free manner. The main source for non-idealities is the performance of the analog-to-digital converter. A digital lock-in amplifier is shown in
Phase-Synchronous Processing:
Phase-synchronous processing (PSP) can be applied if a signal of interest is periodic and if knowledge of the fundamental frequency f0 of the signal is available. In PSP, a given number of periods of the signal of interest is combined in order to obtain a phase-domain signal. A block diagram of a PSP unit is depicted in
A well-known instance of this type of processing is phase-synchronous averaging, also known as time-synchronous averaging: multiple period snapshots are averaged in order to reduce noise components of the input signal.
In a digital implementation of PSP, the input signal s(t) and the reference signal r(t) are first converted to digital values. The subsequent processing is then carried out in the digital domain (see
It is a general object of the present invention to provide a lock-in amplifier of improved versatility.
In a first aspect, this and further objects of the invention are achieved by a lock-in amplifier comprising
an LIA unit having
a PSP unit having
In another aspect, the invention relates to a lock-in amplifier comprising
a signal input for receiving an input signal s(t),
a phase extraction unit generating a phase value indicative of a current phase of a periodic reference signal,
a demodulator generating an unfiltered LIA-signal by multiplying said input signal and said reference signal,
a low-pass filter connected to said demodulator and filtering said unfiltered LIA-signal for generating a filtered LIA output signal,
a value-phase association unit connected to said phase extraction unit for receiving said phase value and adapted to associate values of said input signal to said phase value and to thereby generate phase-associated signal values, and
a signal processor connected to said value-phase association unit and calculating at least one function of said phase-associated signal values for generating a PSP output signal.
Hence, the present invention proposes the integration of a PSP unit into a lock-in amplifier. Even though lock-in amplifiers as well as PSP units have been used for many decades, a combination of the two types of devices has, to the inventors' present understanding, never been made. Such a combination provides numerous advantages.
In particular, the PSP output signal can be used as a basis to provide a wealth of additional information that is not available from the LIA output, such as frequency-domain information or time-domain information. For example, a real-time display of transients that are orders of magnitude faster than the reference frequency can be achieved when analyzing a short signal. Immediate feedback on harmonic distortions of the LIA signal can be obtained (harmonic analyzer), or statistical time-domain analysis tools can be provided that go beyond the accurate measurement of the signal RMS amplitude and that allow to make qualified statements regarding the signal waveform.
The present invention also provides the basis for a completely novel approach to build a multi-frequency lock-in amplifier with a very large number of harmonic frequencies measured concurrently with much more efficient resource use as compared to a multi-demodulator implementation. The number of harmonics analyzed simultaneously is limited by the resolution of the phase signal (which can be very large) and by the memory assigned for the bins (which can be large as well).
In a particularly advantageous embodiment, the value-phase association unit is connected to said reference signal generator, advantageously to its phase extraction unit, for receiving the phase of the reference signal. In other words, a common phase extraction can be used for the LIA unit as well as for the PSP unit.
In another advantageous embodiment the signal input comprises an analog-digital converter generating a series of digitized input signal values si at a sampling interval TS. The demodulator of the lock-in amplifier and the signal processor of the PSP are both connected to this analog-digital converter for receiving the signal values si. Hence, the PSP unit and the LIA unit can share the same analog-digital converter.
The lock-in amplifier further can comprise a reference input, with the reference signal generator being connected to this reference input and adapted to generate the (internal) reference signal from the input signal at the reference input. Alternatively, the (internal) reference signal can be derived from the input signal or from an internal oscillator.
The value-phase association unit is advantageously adapted to generate said phase-associated signal values as a sequence of values sm,k indicative of the value of the input signal at a phase interval φm, wherein k is an index that increases with each new value in said phase interval φm and m is a phase interval index with m=0 . . . M−1. This implies that the phase space is divided into bins. These bins may e.g. be user selected, or they may be an inherent consequence of the limited resolution of the phase extraction unit.
The invention will be better understood and objects other than those set forth above will become apparent when consideration is given to the following detailed description thereof. Such description makes reference to the annexed drawings, wherein:
Device Overview:
The lock-in amplifier of
Further, the device has a signal input 6 for receiving an input signal s(t) and a reference input 7 for receiving a reference source signal r(t).
LIA unit 1 provides the lock-in amplifier functionality of the device. It comprises a reference signal generator 9 which includes a phase extraction unit 10 that generates a phase value Φ(t) (with 0≦Φ(t)<2π) indicative of the current phase within the phase cycle of a reference signal. This phase value Φ(t) is fed to a phase-to-amplitude conversion unit or synthesizer 11, which also forms part of the reference signal generator 9 and generates the values sin (Φ(t)) and cos (Φ(t)) which represent the (internal) periodic reference signal at a fundamental frequency f0. The reference signal is fed to a demodulator 12, which e.g. multi-plies the reference signal with the input signal s(t), thereby generating an unfiltered LIA-signal 13. This unfiltered LIA-signal is fed to a low-pass filter 14 for generating a filtered LIA output signal d(t). Low-pass filter 14 can be any suitable device with a cut-off frequency lower than the frequency of the reference signal. The filtered LIA-signal d(t) at the output of low-pass filter 14 is fed to interface unit 3 to be displayed on a display 16, e.g. in the form of an RMS value and a phase.
PSP unit 2 comprises a value-phase association unit 20 adapted to associate the values of the input signal s to the phase Φ of the reference signal and to thereby generate “phase-associated signal values” sΦ.
In an analog embodiment of the device, the number of possible values of phase Φ is unlimited. However, in an advantageous embodiment, value-phase association unit 20 will be implemented as a digital device. In this case, the number of phase values is limited. Further, the number of phase values to be distinguished can also be limited by binning, as described further below. Therefore, for the embodiments described in the following, it will be assumed that there is a limited number of phase intervals φm, with m=0 . . . M−1, that are of interest. In this case, value-phase association unit 20 will generate a series of values sm,k indicative of the value of the input signal s(t) in phase interval φm. k is an index that increases with each new value in said phase interval φm.
For example, for evenly distributed phase intervals between 0 and 2π, the interval φm is the interval [2π·m/M, 2π·(m+1)/M). The signal in phase interval φm will differ between the periods of the reference signal, i.e. value-phase association unit 20 will generate a series of values sm,k.
The phase-associated signal values sm,k are fed to a PSP signal processor 21, which calculates at least one function Γ(sm,k) thereof. For example, function Γ(sm,k) may e.g. be a vector-valued function providing the average am of the values sm,k averaged over a number K of the most recently measured values in phase interval φm.
The result of the function Γ(sm,k), i.e. the output of PSP signal processor 21, can be made available on a device output in the form of an analog voltage or a digital value.
The device shown in
In the embodiment of
Alternatively, the reference source signal may also be generated internally, e.g. by an oscillator 25 built into the lock-in amplifier, as shown in dotted lines in
Yet another alternative embodiment is shown in
(It must be noted that
Digital Implementation:
As can be seen, the signal input 6 of the device comprises a first analog-digital converter 30 generating a series of digitized input signal values si at a sampling interval TS. The sampling times are advantageously not in a fixed phase relationship with the reference signal, i.e. they are asynchronous thereto, but they are advantageously much shorter than a period of the reference signal.
Similarly, the reference source signal is also fed to a second analog-digital converter 31, which, in a simple embodiment, may be a comparator. The values from analog-digital converter 31 are fed to a phase synchronizer 32 and a phase accumulator 33, which form part of phase extraction unit 10. Phase synchronizer 32 and phase accumulator 33 form a digital PLL as known to the skilled person.
Phase accumulator 33 provides, for each sampling interval i, a phase value Φi, which indicates the current phase associated to the sampling interval i.
The output values Φi from phase accumulator 33 are fed to phase-to-amplitude conversion unit or synthesizer 11, which generates the values cos (Φi) and sin (Φi) to be fed to demodulator 12. Demodulator 12 calculates, for each sampling interval i, the values si·sin (Φi) and si·cos (Φi), which are then fed to low-pass filter 13 for digital filtering. The filtered signals di (which represent e.g. the real and imaginary part of the input signal at the frequency of the reference signal) are then fed to user interface unit 3 for being displayed on display 16.
Value-phase association unit 20 is connected to phase extraction unit 10 for receiving, for each sampling interval i, the associated phase value Φi. Using this phase value Φi, it determines a phase interval φk that the phase value falls into. For this purpose, the device defines a plurality of non-overlapping phase intervals φm with m=0 . . . M−1 in most cases with M>1, typically M>>10. Value-phase association unit 20 attributes phase value Φi to the phase interval φm that value Φi falls into. Hence, over the course of several periods of the reference signal, value-phase association unit 20 generates, for each phase interval φm, a series sm,k of values indicative of the value of the input signal s(t) in phase interval φm.
(Note: More details on the definition of the phase intervals φm are given below, in the section “Binning”).
PSP signal processor 21 performs a mathematical operation on at least some of the values sm,k, thereby generating the PSP output signal as described above.
Binning:
As mentioned above, value-phase association unit 20 advantageously associates each sampled input value with a phase interval φm, and this phase interval is derived from the current phase value Φi (or, in an analog device, Φ(t)). Theoretically, in a digital implementation, there could be a phase interval φm associated to each possible phase value Φ. However, the resolution of the phase value Φ is typically high-advantageously, phase accumulator 33 has a length of at least 32 bits, in particular at least 40 bits, e.g. 48 bits. In such a case, it is impracticable to define a corresponding number of e.g. M=248 phase intervals.
Typically, the number M of phase intervals will be much smaller than the number of different possible values of phase value Φ provided by phase extraction unit 10. Typically, the number M will be larger than 1, in particular larger than 8, e.g. 256 or 1024. It must be noted, however, that M may also be 1, e.g. if PSP unit 2 only comprises a boxcar as described below.
In a simple embodiment, the phase intervals φm can be defined to be equidistantially distributed over the range [0 . . . 2π) by defining φm=[2π·m/M, 2π·(m+1)/M), as mentioned above.
In a more advanced embodiment, the present device can comprise a binning selector 35 that comprises user operatable controls operated through interface unit 3. Binning selector 35 allows the user to define the phase intervals φm. For example, the user operatable controls of binning selector 35 allow the user to select the number M of bins, the lower-bound frequency Φmin of the first bin φ0 and the upper-bound frequency φmax of the last bin φM-1. This information is fed to a phase binning unit 36, which is adapted to determine the phase interval φm for each phase si of the input values si.
Phase binning unit 36 stores then stores input value si, or a processed value derived therefrom, in a location of a memory 37, which location is attributed to the attributed phase interval φm. If a value does not fall into any of the intervals φm, it can e.g. be discarded or be stored in a location of memory 37 designated to receive all values not attributed to an interval φm.
In the embodiment shown in
PSP Signal Processor:
Through user interface unit 3, the user can select which of these components is/are to be used and/or how they are to be combined.
Note: The number K of signals to be processed in each phase interval Φm, e.g. in equations (1) or (2) above, may depend on the index m, e.g. when one phase interval receives much more sampled values than another phase interval.
User Interface Unit:
As mentioned, display 16 of user interface unit 3 can be used to display LIA output d(t). In addition to this, it can be used to display the output of PSP unit 2. The user can select which output data is to be displayed.
In a particularly advantageous embodiment, interface unit 3 can display the filtered and/or unfiltered values of the input signal as a function of the phase of the reference signal in real time.
As mentioned, interface unit 3 can also display the spectrum of the input signal, as obtained through spectrum analyzer 43, together with LIA output d(t). The power of the harmonic components of up to half of the number of phase bins can be displayed.
Interface unit 3 can also display the histogram as calculated in histogram generator 41.
Several Phase Extraction Units:
The device may also comprise several phase extraction units and several PSP units if the input signal comprises several frequencies of interest.
A device of the type of
In more general terms, a lock-in amplifier of the type of
Advantageously, the device can also comprise at least two PSP units 2, 2′. One phase extraction unit is attributed to each PSP unit and each PSP unit is adapted to analyze a signal in reference to the phase value of its attributed phase extraction unit.
Advantageously, the output of first PSP unit 2 can be fed as an input to second PSP unit 2′, which e.g. allows to analyze a signal carrying two different frequencies.
Instead of using two separate PSP units 2, 2′, a single PSP unit may be used that has inputs for several phase values Φi, Φ′i from the several phase extraction units 10, 10′ and that calculates a function derived from the phase values and from the sampled input signal and associates it to pairs of the phase values Φ and Φ′.
Notes:
Phase-synchronous processing in PSP unit 2 offers a wide palette of analysis and signal conditioning possibilities, which are very valuable in applications where a lock-in amplifier is used. These include
The presented device is the combination of a lock-in amplifier unit 1 and a phase-synchronous processing unit 2. This combination leads to a multitude of valuable signal analysis and conditioning possibilities. Amongst others, these possibilities include (i) extraction of time-domain properties of the input signal, (ii) extraction of statistical properties of the input signal, (iii) extraction of frequency-domain properties of the input signal, and (iv) preconditioning of the lock-in input signal.
While there are shown and described presently preferred embodiments of the invention, it is to be distinctly understood that the invention is not limited thereto but may be otherwise variously embodied and practiced within the scope of the following claims.
Number | Name | Date | Kind |
---|---|---|---|
3764924 | Caplan et al. | Oct 1973 | A |
4263558 | Mitter | Apr 1981 | A |
4511848 | Watson | Apr 1985 | A |
4542346 | McNeilly | Sep 1985 | A |
4807146 | Goodrich et al. | Feb 1989 | A |
4914677 | Yamaguchi et al. | Apr 1990 | A |
5210484 | Remillard et al. | May 1993 | A |
5371588 | Davis et al. | Dec 1994 | A |
6097197 | Matsuyama et al. | Aug 2000 | A |
6618148 | Pilgrim et al. | Sep 2003 | B1 |
6823724 | Kobayashi et al. | Nov 2004 | B1 |
8180309 | Kimmig et al. | May 2012 | B2 |
20030137216 | Tamayo de Miguel et al. | Jul 2003 | A1 |
20060148441 | Zinser | Jul 2006 | A1 |
20070007956 | Min | Jan 2007 | A1 |
20070026830 | Guilford | Feb 2007 | A1 |
20070272005 | Abe et al. | Nov 2007 | A1 |
20090115416 | White et al. | May 2009 | A1 |
20100074371 | West | Mar 2010 | A1 |
20100241009 | Petkie | Sep 2010 | A1 |
20110074476 | Heer et al. | Mar 2011 | A1 |
20120313697 | Hafizovic et al. | Dec 2012 | A1 |
Entry |
---|
Time Synchronous Averaging, Copyright 2009, Crystal Instruments. |
Signal Recovery, What is a Boxcar Averager? Technical Note TN 1005, V1.0 12/04UK 2004 AMETEK Advanced Measurement Technology, Inc. |
PerkinElmer Instruments, What is a Lock-in Amplifier? Technical Note TN 1000 V2.1 04/00UK PerkinElmer Inc. 2000. |
Silicon Labs, AN575, Introduction to FPGA-based ADPLLs, Rev. 0.1 3/11 Copyright 2011 by Silicon Laboratories AN575. |
Cova, S. et al., Versatile digital lock-in detection technique: Application to Spectrofluorometry and other fields, Rev. Sci. Instrum. vol. 50, No. 3, Mar. 1979 Digital Lock-in Detection. |
Optronic Laboratories, Application Note (A12), The Benefits of DSP Lock-in Amplifiers, Revision: A, Sep. 1996. |
PerkinElmer Instruments, The Digital Lock-in Amplifier, Technical Note TN 1003, V2.0 04/00UK PerkinElmer Inc. 2000. |
Gaspar, J., et al., Digital lock in amplifier: study, design and development with a digital signal processor, Microprocessors and Microsystems 28 (2004) 157-162. |
Sonnaillon, M., et al., A low-cost, high-performance, digital signal processor-based lock-in amplifier capable of measuring multiple frequency sweeps simultaneously, Review of Scientific Instruments, 76 024703 (2005) American Institute of Physics. |
Stefani, A., et al., Diagnosis of Induction Machines' Rotor Faults in Time-Varying Conditions, IEEE Transactions on Industrial Electronics, vol. 56, No. 11, Nov. 2009. |
Benstetter, G., et al. A review of advanced scanning probe microscope analysis of functional films and semiconductor devices, Thin Solid Films, 517 (2009) 5100-5105. |
Jacobs, H., et al., Practical aspects of Kelvin probe force microscopy, Review Scientific Instruments, vol. 70, No. 3, Mar. 1999. |
Glatzel, T., et al. Amplitude or frequency modulation-detection in Kelvin probe force microscopy, Applied Surface Science, 210 (2003) 84-89. |
Fukuma, T., et al., Surface potential measurements by the dissipative force modulation method, Review of Scientific Instruments, vol. 75, No. 11, Nov. 2004. |
Number | Date | Country | |
---|---|---|---|
20140218103 A1 | Aug 2014 | US |