This application claims priority under 35 U.S.C. §119 to EP Application 05405031.5 filed in Europe on Jan. 21, 2005, and as a continuation application under 35 U.S.C. §120 to PCT/CH2006/000037 filed as an International Application on Jan. 17, 2006, designating the U.S., the entire contents of which are hereby incorporated by reference in their entireties.
The invention relates to a method and a device for characterizing the linear properties of an electrical multi-port component. It also relates to a method for modeling an electrical system with at least one component characterized in this manner.
The linear properties of electrical components with multiple ports are generally characterized by one of the characteristics matrices, e.g. the impedance or transmittance matrix. These matrices can be measured using suitable circuitry.
In general, all elements of the characteristics matrices are frequency dependent, and therefore the measurements must be carried out for different frequencies.
It has been found that conventional methods of measurement may provide poor results because limited precision of the measurement devices and electric noise, in particular if different elements or eigenvalues of the characteristics matrices strongly differ in magnitude. In these cases, information may be lost. On the other hand, the interactions between different electrical components or subsystems in a system can only be described precisely if the properties of the characteristics matrices are well known.
The invention relates to the closest state of the art as shown in the article by Si. Fang, “Electrical modeling of main injector dipole magnets”, Fermi National Accelerator Laboratory (Mar. 17, 1995). Fang discloses a device for characterizing the linear properties of a five-port electrical component, which in this case is a dipole magnet. The device has voltage sources and current sensing units for electrical measurement of the admittance matrix elements as a function of frequency.
In the User's Guide by Agilent Technologies, “Agilent 4155C/4156C Semiconductor Parameter Analyzer”, Volume 1, General Information, Agilent Part No. 04156-90010, Edition 1 (January 2001), a device for characterizing the linear properties of an electrical component with several ports is disclosed. The device has dc or pulsed voltage sources, current monitoring units and a remote control unit for automated measurement. The device performs both measurement and analysis of measurement results.
U.S. Pat. No. 4,156,842 A discloses a system for characterizing the linear properties of an electrical network having at least one port. The device uses high-frequency signal generators and voltage and current sensing units for automated measurement.
In the article of P. Guillaume et al., “Parametric Identification of Two-Port Models in the Frequency Domain”, IEEE Instrumentation and Measurement Technology Conference, p.263-271, Vol. Conf. 8, Atlanta (May 14, 1991), a method and device for characterizing linear two-ports is disclosed. The input and output voltages and currents are measured simultaneously in the frequency band of interest. An analysis of the measurement data is presented that takes care of noise and calibration errors in the input-output data.
In the cited state of the art a single measurement procedure is performed and refined analysis methods are disclosed for improved estimation of the linear properties of the electrical system.
Hence, the problem to be solved by the present invention is to provide an improved method and device for characterizing the linear properties of an electrical multi-port component. This problem is solved by the method and device according to the independent claims.
Accordingly, the method for characterizing a component having n>1 ports contains an “estimation procedure” in which an estimated admittance matrix Y′ is determined by applying voltages to the ports of the component and measuring the response of the component. The estimation procedure can e.g. consist of a conventional measurement of the admittance matrix Y′ by applying a voltage to one port, grounding all other ports, measuring the current at each port, and repeating this procedure for all ports.
The method further comprises a “measurement procedure” in which several voltage patterns uk are applied to the port. The voltage patterns correspond to the eigenvectors vk of the estimated admittance matrix Y′, wherein “correspond” is to express that the pattern uk is substantially (but not necessarily exactly) parallel, i.e. proportional, to the (normalized) eigenvector vk and its corresponding eigenvalue λk. For each applied voltage pattern uk, the response of the component is measured.
As it has been found, applying voltage patterns uk corresponding to the eigenvectors of the admittance matrix allows for obtaining a more accurate description of the component, even if the eigenvalues of the admittance matrix differ substantially from each other.
The response of the device is advantageously measured by measuring, for each applied voltage pattern uk, the current pattern ik at the ports.
The device according to the invention is able to carry out this type of measurement automatically on a device having n>1 ports.
In another aspect, the invention is directed to a device that is able to automatically determine the linear response of a component having n>2 ports by means of n voltage generators for generating a voltage for each port, and n current sensors for sensing the current at each port, using the method described here.
Note: Throughout this text, bold face upper case letters, such as Y, are used to denote matrices, bold face lower case letters, such as u or uk, are used to denote vectors, and non-bold letters, such as λk, are used to denote scalars or components of matrices or vectors.
When talking about “linear properties” of the component, this term is to be understood as encompassing any property that is exactly or close to linear as long as the property fulfills the mathematical relations outlined below with sufficient accuracy within the range of currents and voltages of interest.
Further embodiments, advantages and applications of the invention are given in the dependent claims as well as in the now following detailed description with reference to the figures:
General Measurement Principle:
i=Y·u. (1)
The general principle of measurement according to the present invention is based on an estimation procedure and a measurement procedure. In the estimation procedure, an estimated admittance matrix Y′ is determined, in the measurement procedure a more accurate measurement is carried out.
In the estimation procedure, the elements of the estimated admittance matrix Y′ can e.g. be measured directly using conventional methods. The diagonal elements Y′ii can e.g. by measured by applying a voltage ui to port pi and measure the current ii at the same port while all other ports are short-circuited to zero volt, i.e. Y′ii=ii/ui while uj=0 for i≠j. The other elements Y′ij of the matrix can be measured by applying a voltage ui at port pi while setting all other ports to zero volt and measuring the current ij at port pj, Y′ij=ij/ui while uj=0 for i≠j.
Other conventional methods for measuring the estimated impedance matrix Y′ in the estimation procedure can be used as well.
In general, the estimated admittance matrix Y′ has n eigenvalues λ1 . . . λn and n corresponding (normalized) eigenvectors v1 . . . vn for which
Y′·vk=λk·vk. (2)
Once the estimated admittance matrix is known, its eigenvectors vk can be calculated.
In a measurement procedure following the estimation procedure, several (in general n) voltage patterns uk=(u1k . . . unk) are applied to ports p1 . . . pn of component 1. Each voltage pattern uk corresponds to one of the eigenvectors vk. For each applied voltage pattern uk, a response of the component is measured, in particular by measuring the induced current pattern ik.
As mentioned above, voltage pattern uk corresponds to (normalized) eigenvector vk (which is one of the n normalized eigenvectors of the admittance matrix), namely in the sense that the voltage pattern uk is substantially parallel, i.e. proportional, to the eigenvector vk corresponding to eigenvalue λk. Theoretically, using uk∝vk would be the best solution, but a device generating the voltage patterns uk will, in general, not be able to generate voltage patterns matching the eigenvectors exactly due to discretization errors. Methods for handling devices with limited resolution for generating the voltage patterns will be addressed below.
Once the measurement procedure is complete, the voltage patterns uk and the corresponding current patterns ik fully characterize the linear response of component 1.
In general, the admittance matrix Y is frequency dependent. For fully modeling the behavior of component 1 in a network, the linear response of component 1 should be known for an extended frequency range, e.g. from 50 Hz to several MHz. For this reason, the estimation procedure is carried out at a plurality of frequencies ωi in the given range.
Advantageously, for each estimation procedure, the eigenvalues λk(ωi) at the given frequency ωi are calculated. Then, the most critical frequencies are determined, which are those frequencies where the eigenvalues reach a local maximum or minimum or, in particular, where the absolute ratio between the largest and smallest eigenvalue has a maximum or exceeds a given threshold. These critical frequencies are of particular interest, either because they are indicative of a resonance of component 1 or because they show that some of the estimated eigenvalues may be of poor accuracy and the described measurement procedure is required to increase the accuracy.
It is principally possible to divide the desired frequency range in a number of frequency windows and to calculate the most critical frequencies in each frequency window.
For each or at least some of the critical frequencies, the measurement procedure described above is carried out to refine the measurement. In addition or alternatively thereto, the measurement procedure can be carried out at other points within the frequency range of interest.
The frequencies ωi where measurements are carried out can be distributed linearly or logarithmically over the range of frequencies of interest. In an advantageous embodiment, though, the density of measurement frequencies ωi close to the critical frequencies as mentioned above is larger than the density of measurement frequencies ωi in spectral regions far away from the critical frequencies. This allows to obtain a more reliable characterization of the component.
The Measurement Device:
A general measuring device 2 for carrying out the invention is disclosed in
For the device of
φ=u+Z·i, (3)
where φ=(φ1 . . . φn) are the voltages of the voltage sources, u=(u1 . . . un) the input voltages at the ports, and Z is a diagonal matrix with the diagonal elements Z1 to Zn.
Combining equations (1) and (3) gives the following relationship between the input voltages and the applied voltages:
u=(I+Z·Y)−1·φ. (4)
where I is the n×n identity matrix.
As mentioned above, the applied voltages u should correspond to the eigenvectors vk of the estimated admittance matrix Y′. In general, however, it will not be possible to match this condition exactly because the voltage sources will not be able to generate any arbitrary voltage values but only a discrete set of values. If the number of voltage values that can be generated is small, the impedances Z1 to Zn can be designed to be adjustable as well in order to obtain a larger number of different input voltages u.
The input voltage vector uk can be expressed as a linear combination of the eigenvectors v1, i.e.
Combining equations (5), (1) and (2) yields
Hence, to maximize the influence of the k-th eigenvalue on the input current vector i in proportion to the other eigenvalues, the following error function must be minimized
In other words, for each eigenvalue λk, the coefficients α1 . . . αn must be found (among the set of possible coefficients, which is a finite set due to the discretization inherent to measuring device 2) for which the term of equation (6) is smallest.
If measuring device 2 has adjustable voltage sources and impedances as shown in
α=[v1 . . . vn]−1·(I+Z·Y′)−1φ. (7)
A measuring device for carrying out the above method should, in general, comprise n voltage generators that are programmable to apply the voltage pattern u to the n ports of device 1. Further, it should comprise n current sensors to measure the currents i. It should be adapted to apply at least n suitable voltage patterns to the ports consecutively for measuring the linear response of the component automatically. This is especially advantageous for components 1 having more than two ports because using this kind of automatic measurement on components with n>2 ports provides substantial gains in speed and accuracy while reducing the costs.
Advantageously, the measuring device should comprise a control unit for carrying out the measurement using the estimation and measurement procedures outlined above.
One possible embodiment of a measuring device 2 is shown in
Another possible embodiment of a measuring device is shown in
Further Processing of the Results:
As mentioned above, the described measurement procedure yields, for a given frequency, a set of voltage patterns uk and the corresponding current patterns ik, which fully characterize the linear response of component 1 at the given frequency.
The values uk and ik for k=1 . . . n can, in principle, be converted into a more accurate estimate of the admittance matrix Y or the corresponding impedance matrix. However, if the smallest and largest eigenvalues of admittance matrix Y differ by several orders of magnitude, such a matrix is difficult to process numerically with floating point calculations due to rounding errors and limited accuracy of the numerical algorithms. Hence, in an advantageous embodiment of the present invention, the values uk and ik are used directly for further processing, without prior conversion to an admittance or impedance matrix Y.
For example, the results of the measurement procedure can e.g. be used for modeling the electrical properties of the component 1 or of a network that component 1 is part of. Such a model can e.g. be used to analyze the stability of the network in general or its response to given events in particular.
The method described here can be used for characterizing a variety of components, such as electrical motors, transformers, switches, transmission lines, etc.
Number | Date | Country | Kind |
---|---|---|---|
05405031 | Jan 2005 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
4156842 | Brooks et al. | May 1979 | A |
4300182 | Schweitzer, III | Nov 1981 | A |
5396172 | Lat et al. | Mar 1995 | A |
5502392 | Arjavalingam et al. | Mar 1996 | A |
5517422 | Ilic et al. | May 1996 | A |
6011345 | Murray et al. | Jan 2000 | A |
6035265 | Dister et al. | Mar 2000 | A |
6054867 | Wakamatsu | Apr 2000 | A |
20020011848 | Coffeen | Jan 2002 | A1 |
20040164745 | Ryder | Aug 2004 | A1 |
Number | Date | Country |
---|---|---|
0 443 835 | Aug 1991 | EP |
2 411 733 | Sep 2005 | GB |
WO 0184169 | Nov 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20070285109 A1 | Dec 2007 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/CH2006/000037 | Jan 2006 | US |
Child | 11826795 | US |