ap-5-11.dvi Acta Polytechnica Vol. 51 No. 5/2011 A Wideband Low-Pass Filter for Differential Mode Distortion M. Brejcha Abstract This paper deals with the solution for a wideband low-pass filter that can be used for filtering the input currents of switching converters, which are distorted by the switching frequency of PWM. Initially, the filter was proposed for the special type of AC converter, which is described in the paper. However, these solutions can also be used in the inputs of activePFCconverters and in the outputs of PWMconverters, where there are similar problemswith switching frequency. The frequency band of the filter is given by the switching frequency of the filtered device and by the demands of EMC standards. This makes the filter able to work in the frequency band from 10 kHz to 30 MHz. To ensure such a frequency band, the filter should be proposed with two sections, each for a specific part of the band. Keywords: filter, filtering, low-pass, wideband, EMC, differential mode. 1 Introduction Each realization of a passive filter is affected by the frequency dependence of the circuit component. The value of themain parameter of a component depends on other parasitic properties. When considering a coil, the main parameter is the inductance, and the parasitic parameters are the resistivity of the wires and the capacity among the turns. The resistivity affects the quality factor of the coil, and the capac- ity defines its serial resonant frequency. Further we will deal with the common circuit parts in passive filters, which are the coils and the capacitors. The equivalent circuits of both circuit parts are depicted in Figure 1. The use of coils and capacitors is lim- ited by the resonant frequency, because when they achieve this frequency their reactance changes sign. The values of the parasitic parameters are associated with the size and construction of the circuit part. It can be said that the size of capacitors and coils are related to thevalueof themainparameterand the re- quired reactive power. In case of inductors, if induc- tance valuewas increasedat the same reactivepower, then the size of the coil would have to be bigger. As stated above, the value of the parasitic parameters (resistance and capacitance) would be increased. Ordinary filters are usually proposed for filtering the distortion from 150 kHz to 30 MHz. This fre- quency band is defined in theEMCstandards. These filters are not difficult to design, because the fre- quency boundaries are relatively close. The circuit parts are relatively small, and their parasitic proper- ties do not affect the frequency response so much. A problem arises when we try to reduce the cut- off frequency of the filter, because we have to in- crease the inductance and capacitance values. A fil- ter with a relatively low cut-off frequency had to be used for the special AC converter shown in Figure 2. This four-quadrant converter is based on the topol- ogy of a buck-converter, which is widely used in DC circuits. The amplitude of the output fundamental harmonic voltage is proportional to the duty-cycle of the switching. To obtain the fundamental harmonic function, the output filter has to be able to filter the switching frequency (about 20 kHz). In this case we should design the filter as two ormore parts, each for a specific frequency band. Fig. 1: Equivalent circuits for a) inductors and b) capac- itors Fig. 2: An AC converter based on a buck-converter 2 Dependency of the parameters on frequency All circuits parts used in the proposed filter were measured to obtain the dependency of the main pa- rameter on frequency. Weused 10nF and 680nF foil 14 Acta Polytechnica Vol. 51 No. 5/2011 capacitors and two handmade 56 μH and 3.18 mH inductors in the filter. We plotted the absolute impedance characteristic and the phase angle char- acteristic in all cases to make it easier to compare the plots with each other. 2.1 Capacitors The characteristic impedance decreases with fre- quency in both cases of capacitors until the reso- nant frequency is reached. This correspondswith the equation: Z ≈ XC = 1 2π · f · C (Ω; Hz; F) (1) In equation 1, f is frequency and C is capacity. After reaching the resonant frequency the impedance begins to rise, because the capacitor starts to behave as an inductor. Note that the resonant frequency of the 10 nF capacitor (Figure 3) is higher than the re- sonant frequency of the 680 nF capacitor (Figure 4). This is because of the size of the parts. The 680 nF has to have larger electrodes to obtain higher capac- ity. The parasitic inductance increases, because the electrodes also behave as wires. Fig. 3: The impedance of capacitor 10 nF Fig. 4: The impedance of capacitor 680 nF The resonant frequency of a 680 nF capacitor is close to 1 MHz. If this capacitor was used in a filter, an unwanted shape of the frequency response would appear above this frequency. 10 nF capacitors have lower parasitic inductance, and they can be used up to 10 MHz. 2.2 Inductors There is a similar situation in the case of inductors. At the beginning, the trace of the impedance in- creases in both types of inductors. This corresponds to the equation: Z ≈ XL =2π · f · L (Ω; Hz; H) (2) In equation (2), f is the frequency and L is the in- ductance in the. As in the previous case, after reach- ing the resonant frequency the parasitic parameters becomedominant and the inductor behaves like a ca- pacitor. An inductor with a higher inductance value has a lower resonant frequency. This is easy to un- derstand, when we realize that the smaller inductor has only 10 turns on a ferrite core and the bigger inductor has 110 turns on an iron powder core. You may observe that some breaks occur in the tracebehind the resonant frequency inFigure6. This is because the length of the coiledwires exceeded the 1/4 of the wave length of the signal. This is another parasitic phenomenon that affects the resulting fre- quency response of the filter. The inductor inFiure 6 certainly should not be used for frequencies higher than 500 kHz. Fig. 5: The impedance of inductor 56 μH Fig. 6: The impedance of inductor 3.18 mH 15 Acta Polytechnica Vol. 51 No. 5/2011 3 Realization of the filter We will further consider the realization of the filter, for which the tolerance scheme is shown in Figure 7. Our goal is to propose a filter with high attenuation between 20 kHz and 30 MHz. The terminal resistors will be considered to be 50 Ω. If we use the Butter- worth approximation for the coefficients of the filter, we obtain the values of the circuit parts for the π- section shown in Table 1. These are the same values of the inductors and capacitors as were measured in section 2. Their frequency characteristics are shown in Figure 4 and Figure 6. Table1: Filter realization byButterworthApproximation R1 (Ω) C1 (nF) L1 (mH) C2 (nF) R2 (Ω) 50 680 3.18 680 50 Fig. 7: Prescribed tolerance scheme for the filter The reader will have noticed that this realization of the filter can be used only up to approximately 1 MHz. Above this frequency, the attenuation of the filter will begin to decrease. To solve this problem we should add another section of the filter, which will workwell between 1 MHz and 30 MHz and does not affect the previous section of the filter. 3.1 The corrective section of the filter The corrective section of the filter can be just of the 2nd order, because it needs to hold only high attenua- tion at high frequency. The high level of attenuation should be reached by the previous low-frequency sec- tion. The first task is to ensure that the corrective sec- tion of the filter does not affect the previous section. This can be achieved by a progressive sequence of the sections. If the cut-off frequency of the corrective section is much higher than the cut-off frequency of the filter, then it does not affect the passband. The influence of the corrective section is then negligible, and the filter behaves as if it were terminated by R1 and R2. This is because the values of inductors and capacitors in the corrective section are then much lower than in the filter. Lower values of the main parameters also mean lower values of the parasitic parameters of the circuit parts. We propose a cut-off frequency at 100 kHz for this design of a corrective section. The next task is to reflect the impedance of the filter section in solution of the corrective section. We cannot countwith the terminal resistor R1 anymore, because the impedance of the filter section is not neg- ligible. However the resulting output impedance of the filter is very lowat high frequency, because of the large value of capacitor C2. We can therefore con- sider the input impedance of the corrective section to be zero. We therefore design the section with termi- nal resistors 0 and R2. The proposed values of the circuit parts, using the Butterworth approximation for both sections, are shown in Table 2. Table 2: Filter design with corrective section R1 C1 L1 C2 L2 C3 R2 (Ω) (nF) (mH) (nF) (μH) (nF) (Ω) 50 680 3.18 680 56 10 50 Fig. 8: Filter topology 3.2 Prototype of the filter Using the method described above, we made a pro- totype of the filter, which is shown in Figure 9. The filter was made to attenuate the differential mode of distortion. The circuit partswere solderedon the top layer of the PCB. The bottom layer was grounded to the shielding. To attenuate possible interference among the circuit parts, the inductor L1 (3.18 mH) was enclosed in its own shielding. The input and the output of the filter were realized byBNC connectors. Fig. 9: The prototype of the filter 16 Acta Polytechnica Vol. 51 No. 5/2011 The frequency response of the filter prototype was measured, and the result is shown in Figure 10. There is only low attenuation in the passband up to 5 kHz. This corresponds to the demands for the de- sign. After crossing the cut-off frequency, the trace begins to decrease. The maximum of attenuation is close to 100 dB at approximately 200 kHz. The cor- rective section should also function at this frequency. Attenuation higher than 85 dB is then held up to 30 MHz. Fig. 10: Frequency response of the filter prototype 4 Conclusion We have described a method for designing a wide band low-pass filter by adding the corrective section to the filter. The resulting frequency response of the filter meets the requirements, and high attenuation has been retained up to 30MHz. However, the other circuit parts make the filter more expensive and in- crease its size. The larger dimension of the filter can lead to other problems with parasitic effects. Acknowledgement The research presented in this paper was sup- ported by the Czech Ministry of Education under grant No. MSM6840770017 — Rozvoj, spolehlivost a bezpečnost elektroenergetických systémů. References [1] Cetl, T., Papež, V.: Konstrukce a realizace elek- tronických obvodů. Praha : VydavatelstvíČVUT, 2002. 263 s. ISBN 80-01-02463-6. [2] Bičák, J., Laipert, M., Vlček, M.: Lineární ob- vody a systémy. Praha : Česká technika—nakla- datelství ČVUT, 2007. 204 s. ISBN 978-80-01-03649-5. [3] Davídek, V., Laiperet, M., Vlček, M.: Analogové a číslicové filtry. Praha : Nakladatelství ČVUT, 2006. 345 s. ISBN 80-01-03026-1. [4] Chen, W.-K., et al.: Passive, Active and Digi- tal Filters. 3rd ed. Chicago, U.S.A. : CRC Press, 2009. ISBN 978-1-4200-5885-1. [5] Faktor,Z.: Transformátory a cívky. dotisk 1. vyd. Praha : Ben, 2002. 400 s. ISBN 80-86056-49-X. About the author Michal BREJCHA was born 26 March 1983 in Prague. He attended SPŠE Františka Křižíka sec- ondary schoolbetween1999and2003,wherehe stud- ied the electrotechnic section. He then started to study electric power engineering at CTU in Prague. There he was awarded his bachelor degree and his master degree in Electrotechnology in 2006. He is now studying as a PhD student in the same depart- ment of the Faculty of Electrical Engineering. Michal Brejcha E-mail: brejcmic@fel.cvut.cz Dept. of Electrotechnology Czech Technical University Technická 2, 166 27 Praha, Czech Republic 17