KR100662741B1 - Emi filter design and measuring apparatus having a compensation circuit - Google Patents

Abstract

A filter design for attenuating an EMI(ElectroMagnetic Interference) noise having a compensation circuit and a measuring apparatus thereof are provided to obtain an accurate result without a measuring error due to a filter design and measurement module by using the compensation circuit to minimize a difference of an insertion loss. In a filter design for attenuating an EMI noise having a compensation circuit(50), a filter design and measuring module(40) is connected to an output terminal of an LISN(Line Impedance Stabilization Network)(10) to change a construction of a filter for attenuating the EMI noise generated by a load(20) and measures characteristics of the respective changed filter. The compensation circuit(50) is connected to an output terminal of the filter design and measuring module(40) to compensate a measurement error according to an insertion of the filter design and measuring module(40). And, the compensation circuit(50) is designed so that a first insertion loss when only the LISN(10) is inserted between power and a load(20), is substantially equal to a second insertion loss when the LISN(10) and the filter design and measuring module(40) are inserted between the power and the load(20).

Description

Electromagnetic Noise Reduction Filter Design and Measurement Device with Compensation Circuit {EMI Filter Design and Measuring Apparatus Having a Compensation Circuit}

The following drawings attached to this specification are illustrative of preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to

1 is a diagram schematically illustrating a system for designing and measuring an electromagnetic wave attenuation filter using a conventional pseudo power network.

2 is a diagram schematically illustrating a system for designing and measuring an electromagnetic wave attenuation filter using a pseudo power network according to the present invention.

FIG. 3 is an equivalent circuit diagram for calculating insertion loss in a state in which only a pseudo power network is inserted between a power supply and a load in the system shown in FIG. 1.

FIG. 4 is an equivalent circuit diagram for calculating insertion loss in the state in which the pseudo power network and the filter design and measurement module are inserted in the system shown in FIG.

The present invention relates to a design and measurement apparatus of an electromagnetic noise reduction filter, and more particularly, by manually or automatically connecting a filter design and measurement module to a Line Impedance Stabilization Network (LISN). An apparatus for designing an attenuation filter, the present invention relates to a design and measurement apparatus of an electromagnetic noise reduction filter minimizing the measurement error due to the filter design and insertion of the measurement module.

In general, electrical and electronic equipment and devices composed of electrical and electronic circuits, when placed in close proximity to each other, generate electromagnetic noise that compromises their original function as a result of electrical or electromagnetic interactions. In particular, the electromagnetic noise has become an increasingly serious problem as the degree of integration of electrical and electronic devices increases with the miniaturization of electrical and electronic devices. Therefore, the electrical and electronic equipment should be designed and manufactured so as not to be influenced by the electromagnetic noise from other equipment, and not to affect the electromagnetic equipment by the electromagnetic noise.

Electromagnetic noise generated in electric and electronic devices includes largely conducted noise that is conducted through power lines and radiated noise that is radiated into the air in the form of electromagnetic waves. Dual radiated noise can be reduced relatively easily by applying well-known suitable grounding and electromagnetic shielding techniques. On the other hand, it is not easy to measure and reduce conduction noise. An expensive pseudo power supply network (LISN) is generally used to measure the conduction noise. In addition, this pseudo power supply network is used not only for the measurement of conducted noise but also for the design of a filter that attenuates electromagnetic noise at a predetermined frequency and the measurement of the characteristic of a designed filter.

That is, as shown in Figure 1, by inserting the artificial power supply network 10 between the conventional commercial power supply (L) and the load 20 to measure the conduction noise of the power supply line, wherein the load 20 and A filter 30 designed to attenuate electromagnetic noise between the pseudo power supply network 10 is connected and the characteristics of the filter 30 are measured at its output terminals (c, a terminals). However, in such a scheme, it is necessary to repeatedly turn off the power of the load 20, change the design of the filter 30, change the design of the filter 30, and measure again until the designed filter 30 sufficiently reduces electromagnetic noise. There is a hassle.

Therefore, Korean Patent Laid-Open Publication No. 2000-282 or 2001-44893 proposes an automated filter design and measurement apparatus. That is, in the system of FIG. 1, instead of the filter 30, a variable filter including a variable capacitor and a variable inductor may be embedded, and filter characteristics may be measured while changing the configuration of the filter manually or automatically by an electrical or mechanical switching operation. The filter design and measurement module 40 is inserted.

The automated filter design and measurement module 40 eliminates the need for the operator to repeat the measurement while changing the filter 30 manually, while measuring errors due to the insertion of the automated filter design and measurement module. There is a problem that occurs. That is, the filter design and measurement module 40 includes various mode selection switches, circuit elements such as signal separation and matching devices, and as a result, the measurement result is different from that of simply inserting the filter 30 alone. . Therefore, there is a problem that the filter designed and optimized by this filter design and measurement module cannot exhibit sufficient electromagnetic noise reduction function in actual use.

The present invention was devised in consideration of the above problems, and even though the design and measurement of the electromagnetic noise attenuation filter using the automated filter design and measurement module, the filter design and measurement with little measurement error by the filter design and measurement module The purpose is to provide a device.

In order to achieve the above technical problem, the present invention provides an electromagnetic noise reduction filter design and measuring apparatus having a compensation circuit for compensating for the measurement error generated by the filter design and measurement module. Here, the compensation circuit is a circuit designed such that the insertion loss when there is only a pseudo power supply network without the filter design and measurement module and the insertion loss when the filter design and measurement module is inserted are almost the same.

That is, the electromagnetic noise attenuation filter design and measurement device according to an aspect of the present invention is connected to the output terminal of the pseudo power supply network, to design and measure a filter for attenuating electromagnetic noise generated by the load and conducted along the power line An apparatus, comprising: a filter design and measurement module coupled to an output of said artificial power supply network for modifying a configuration of a filter for attenuating electromagnetic noise generated by said load and for measuring characteristics of each changed filter; And a compensating circuit connected to an output terminal of the filter design and measuring module, the compensating circuit compensating for a measurement error caused by insertion of the filter design and measuring module, wherein the compensating circuit comprises: the pseudo power supply network between a power supply and the load; The circuit constant is designed so that the first insertion loss when bays are inserted and the second insertion loss when the pseudo power network and the filter design and measurement module are inserted between the power source and the load are substantially equal. It is a circuit.

In addition, according to an embodiment, the compensation circuit includes a resistor, an inductor, and / or a capacitor in which resistance values, inductances, and / or capacitances are set such that the first insertion loss and the second insertion loss are substantially the same.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

2 is a diagram schematically illustrating a system for designing and measuring an electromagnetic wave attenuation filter according to an exemplary embodiment of the present invention.

As shown in FIG. 1, a system for designing and measuring an electromagnetic wave attenuation filter according to the present embodiment includes a pseudo power supply network 10, a load 20, a filter design and measurement module 40, and a compensation circuit 50. ). Here, since the pseudo power supply network 10 and the load 20 are the same as the above-described prior art, description thereof will be omitted.

As described with reference to FIG. 1, the filter design and measurement module 40 includes a variable inductor and a variable capacitor, or a plurality of capacitors having different inductances and capacitances having different inductances therein, thereby providing electrical or mechanical It is possible to change the filter configuration automatically or manually by switching operation. In addition, the filter design and measurement module 40 may be adapted to mount an externally designed filter. In addition, the filter design and measurement module 40 may include a mode selection switch to separately measure common mode noise and differential mode noise among conductive noises. Therefore, the filter design and measurement module 40 makes it easy to configure the filters of various configurations by simple operation, and the characteristics of the configured filters can be easily measured using various mode selection switches.

On the other hand, since the filter design and measurement module 40 is described in detail and commercialized in the aforementioned Patent Publication No. 2000-282 or 2001-44893, it is possible to use a known module as it is without any separate configuration.

As described above, the filter design and measurement module 40 itself includes circuit elements such as various mode selection switches or signal separation and matching devices, so that even when the filter is not configured (in other words, the pseudo power supply network ( Even if the output of 10) is bypassed, measurement results are different from those without the filter design and measurement module 40.

The compensation circuit 50 is used in connection with the rear end of the filter design and measurement module 40 to minimize this measurement error. In the present embodiment, the compensation circuit 50 is formed using the resistor Rc, the inductor Lc, and the capacitor Cc. The principle and specific method of designing the compensation circuit of the present embodiment will be described in detail.

The principle of the compensation circuit of this embodiment is to minimize the measurement error due to the insertion of the filter design and measurement module 40 by making the insertion loss with and without the filter design and measurement module 40 almost equal. That's the principle.

First, FIG. 3 is an equivalent circuit diagram for calculating insertion loss in the absence of the filter design and measurement module 40. That is, FIG. 3 is an equivalent circuit diagram without the filter 30 or the filter design and measurement module 40 in FIG. 1, and directly viewed from the output terminals (c, b terminals) of the pseudo power supply network 10, and Z in FIG. ₁ to Z ₅ are equivalent impedances. 4 is an equivalent circuit diagram for calculating insertion loss when there is a filter design and measurement module 40. That is, FIG. 4 is an equivalent circuit diagram of the filter design and measurement module 40 inserted into the output terminal of the pseudo power supply network 10 in FIG. 1 and viewed from the output terminals c and b terminals, and from Z ₁ to FIG. Z ₄ , Z ₆ and Z ₇ are equivalent impedances. In this case, the filter design and measurement module 40 does not constitute a filter in order to consider only its equivalent impedance purely, that is, sets the mode of bypassing the output of the pseudo power network 10 as it is so that the equivalent impedance ( Z ₁ to Z ₄ , Z ₆ and Z ₇ ) are assumed.

3 and 4, the insertion loss is calculated by the following equation, and the compensation circuit 50 is designed with elements in which circuit constants are set so that the difference in each insertion loss is minimized.

Meanwhile, in FIG. 2, the compensation circuit is illustrated as being composed of a series circuit of an inductor Lc and a capacitor Cc and a parallel circuit of a resistor, but the compensation circuit of the present invention is not necessarily limited to the configuration shown in FIG. 2. . Any other design may be used as long as the design minimizes the difference between the insertion losses described above.

An example of calculating the actual insertion losses and designing a compensation circuit will then be described.

First, in calculating the insertion loss in FIGS. 3 and 4, the impedances of the respective circuit elements L ₁ , C ₁ , C ₂ and R _{1 of the} pseudo power supply network 10 are equivalent as follows.

L ₁ = 50 μH, C ₁ , = ₁ μF, C ₂ = 0.1 μF, R ₁ = 1 kΩ

When the pseudo power supply network 10 is equivalent as described above, the respective equivalent impedances of FIGS. 3 and 4 and the insertion loss in each case are shown in the following table according to each operating frequency.

division frequency Z ₁ Z ₂ Z ₃ Z ₄ Z ₅ Z ₆ Z ₇ Insertion loss 3 circuit 150 kHz 1.1Ω 47.1Ω 10.6Ω 47.6Ω 4.7 kΩ (5 mH) - - 46.8 dB 5 MHz 0.032Ω 1.57kΩ 0.32Ω 47.6Ω 157kΩ (5mH) - - 70.6 dB 30 MHz 0.0053Ω 9.42kΩ 0.053Ω 47.6Ω 942 kPa (5 mH) - - 86 dB 4 circuit 150 kHz 1.1Ω 47.1Ω 10.6Ω 1kΩ - 4.7 kΩ (5 mH) 50Ω 39.7 dB 5 MHz 0.032Ω 1.57kΩ 0.32Ω 1kΩ - 157kΩ (5mH) 50Ω 69.9 dB 30 MHz 0.0053Ω 9.42kΩ 0.053Ω 1kΩ - 942 kPa (5 mH) 50Ω 85.5 dB

From the above results, it can be seen that there is a significant difference between the insertion loss in the absence of the filter design and measurement module (FIG. 3) and in the case of (FIG. 4), especially in the relatively low frequency region.

Therefore, in this embodiment, each circuit element Lc, Cc, and Rc of the compensation circuit is set to Lc = 50 µH, Cc = 1 µF, and Rc = 1 kΩ, respectively, and the insertion loss is calculated. That is, adding such a compensation circuit to the output terminal (c, b terminal) of the circuit of FIG. 4 and calculating the insertion loss, each operating frequency is 46.0dB at 150kHz, 70.63dB at 5MHz, and 85.97dB at 30MHz. This result is almost the same as the insertion loss of each operating frequency in the absence of the filter design and measurement module. Using the compensation circuit of this embodiment, even with the filter design and measurement module, the characteristics of the original filter can be measured with little error. It means that there is.

In addition, the above-mentioned example is only one example which designs the compensation circuit of this embodiment, and of course, the compensation circuit of this invention is not limited to the said example. For example, if the equivalent impedance by the pseudo power supply network or the load is different, the impedance of each circuit element of the compensation circuit should also be different, and if the arrangement of circuit elements of the compensation circuit is different, the impedance will also be different. In short, it is significant that the compensation circuit of the present invention is designed to minimize the difference in insertion loss with and without filter design and measurement module.

The technical problem of the present invention is achieved by the above-described technical configuration, and although the present invention has been described by the limited embodiments and the drawings, the present invention is not limited thereto and the general knowledge in the technical field to which the present invention belongs. It is apparent that various modifications and variations can be made by those skilled in the art within the scope of the technical spirit of the present invention and the claims to be described below.

According to the present invention, in the design of an electromagnetic noise attenuation filter using a pseudo power supply network, an automated filter design and measurement module is used by using a compensation circuit which minimizes the difference in insertion loss according to the filter design and the presence or absence of a measurement module. Even if the electromagnetic noise attenuation filter is designed and measured, accurate results with little measurement error due to the filter design and measurement module can be obtained.

Claims (3)

An apparatus for designing and measuring a filter connected to an output terminal of a pseudo power supply network and attenuating electromagnetic noise generated by a load and conducted along a power supply line, A filter design and measurement module connected to an output terminal of the pseudo power supply network, for changing a configuration of a filter for attenuating electromagnetic noise generated by the load and measuring characteristics of each changed filter; And A compensation circuit connected to an output terminal of the filter design and measurement module and compensating for a measurement error caused by insertion of the filter design and measurement module; The compensation circuit includes a first insertion loss when only the pseudo power network is inserted between a power source and the load, and a first insertion loss when the pseudo power network and the filter design and measurement module are inserted between the power source and the load. 2. An electromagnetic noise attenuation filter design and measurement device, characterized in that the circuit is designed with a circuit constant set such that insertion loss is substantially equal. The method of claim 1, The compensation circuit is characterized in that the electromagnetic noise attenuation filter design comprises a resistor, an inductor and / or a capacitor whose resistance value, inductance and / or capacitance are set such that the first insertion loss and the second insertion loss are substantially equal. And measuring device. The method of claim 2, The compensation circuit is an electromagnetic noise attenuation filter design and measurement device, characterized in that the output circuit of the filter design and measurement module, the series circuit of the inductor and the capacitor and the resistor is connected in parallel.

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