Active EMI reduction explained

In the field of EMC, active EMI reduction (or active EMI filtering) refers to techniques aimed to reduce or to filter electromagnetic noise (EMI) making use of active electronic components. Active EMI reduction contrasts with passive filtering techniques, such as RC filters, LC filters RLC filters, which includes only passive electrical components. Hybrid solutions including both active and passive elements exist.[1] Standards concerning conducted and radiated emissions published by IEC[2] and FCC[3] set the maximum noise level allowed for different classes of electrical devices. The frequency range of interest spans from 150 kHz to 30 MHz for conducted emissions and from 30 MHz to 40 GHz for radiated emissions.[4] Meeting these requirements and guaranteeing the functionality of an electrical apparatus subject to electromagnetic interference are the main reason to include an EMI filter. In an electrical system, power converters, i.e. DC/DC converters, inverters and rectifiers, are the major sources of conducted EMI, due to their high-frequency switching ratio which gives rise to unwanted fast current and voltage transients. Since power electronics is nowadays spread in many fields, from power industrial application to automotive industry,[5] EMI filtering has become necessary. In other fields, such as the telecommunication industry where the major focus is on radiated emissions, other techniques have been developed for EMI reduction, such as spread spectrum clocking which makes use of digital electronics, or electromagnetic shielding.

Working principle

The concept behind active EMI reduction has already been implemented previously in acoustics with the active noise control[6] and it can be described considering the following three different blocks:

The active EMI reduction device should not affect the normal operation of the raw system. Active filters are intended to act only on the high-frequency noises produced by the system and should not modify normal operation at DC or power-line frequency.

Filter topologies

The EMI noise can be categorized as common mode (CM) and differential mode (DM).[7] Depending on the noise component that should be compensated, different topologies and configurations are possible. Two families of active filter exist, the feedback and the feed forward controlled: the first detects the noise at the receiver and generates a compensation signal to suppress the noise; the latter detects the noise at the noise source and generates an opposite signal to cancel out the noise.

Even though the spectrum of an EMI noise is composed by several spectral components, a single frequency at the time is taken into account to make possible a simple circuit representation, as shown in Fig. 1. The noise source

Is

is represented as a sinusoidal source with its Norton representation which delivers a sinusoidal current

IL

to the load impedance

ZL

.

The target of the filter is to suppress every single frequency noise current flowing through the load, and in order to understand how it achieves the task, two very basic circuit elements are introduced: the nullator and the norator.The nullator is an element whose voltage and current are always zero, while the norator is an element whose voltage and current can assume any value. For example, by placing the nullator in series or in parallel to the load impedance we can either cancel the single frequency noise current or voltage across

ZL

. Then the norator must be placed to satisfy the Kirchhoff's current and voltage laws (KVL and KCL). The active EMI filter always tries to keep a constant value of current or voltage at the load, in this specific case this value is equal to zero. The combination of a nullator and a norator forms a nullor, which is an element that can be represented by an ideal controlled voltage/current source.[8] [9] The series and parallel combinations of Norator and Nullator gives four possible configurations[10] of ideal controlled sources which, for the case of feedback topology, are shown in Fig. 2 and in Fig. 3 for the feedback topology.

The four implementation that can be actualized are:[11]

Feedback

To assess the performances and the effectiveness of the filter, the Insertion loss (IL) can be evaluated in each case. The IL, expressed in dB, represents the achievable noise attenuation and it is defined as:

IL=20log10

|Vwithout|
|Vwith|

where

Vwithout

is the load voltage measured without the filter and

Vwith

is the load voltage with the filter included in the system. By applying KVL, KCL and Ohm's law to the circuit, these two voltages can be calculated.If

A

is the filter's gain, i.e. the transfer function between the sensed and the injected signal, IL results to be:
!Type!Filter's gain (A)!Insertion Loss (IL)
(a) I sensing - I injectingCurrent gain

Ic=A*IL

1+A*Zs
Zs+ZL
(b) V sensing - I injectingTrans-impedance gain

Ic=A*VL

1+A
Ys+YL
(c) I sensing - V injectingTrans-admittance gain

Vc=A*IL

1+A
Zs+ZL
(d) V sensing - V injectingVoltage gain

Vc=A*VL

1+A*ZL
ZL+Zs

Larger IL implies a greater attenuation, while a smaller than unity IL implies an undesired noise signal amplification caused by the active filter. For example, type (a) (current sensing and compensation) and (d) (voltage sensing and compensation) filters, if the mismatch between

ZL

and

Zs

is large enough so that one of the two becomes negligible compared to the other, provide ILs irrespective of the system impedances, which means the higher the gain, the better the performances. The large mismatch between

ZL

and

Zs

occurs in most of real applications, where the noise source impedance

Zs

is much smaller (for the differential mode test setup) or much larger (for the common mode test setup) than the load impedance

ZL

, that, in standard test setup, is equal to the

50\Omega

LISN impedance.[12] [13] In these two cases ILs can be approximated to:
!Type!Impedances!Approx. IL
(a) I sensing - I injecting

Zs

>>

ZL

1+A

(d) V sensing - V injecting

Zs

<<

ZL

1+A

On the other hand, in the type (c) (current sensing and voltage compensation) active filter, the gain of the active filter should be larger than the total impedance of the given system to obtain the maximum IL. This means that the filter should provide a high series impedance between the noise source and the receiver to block the noise current. Similar conclusion can be made for a type (b) (voltage detecting and current compensating) active filter; the equivalent admittance of the active filter should be much higher than the total admittance of the system without the filter, so that the active filter reroutes the noise current and minimizes the noise voltage at the receiver port. In this way, active filters try to block and divert the noise propagation path as conventional passive LC filters do. Nevertheless, active filters employing type (b) or (c) topologies require a gain A larger than the total impedance (or admittance) of the raw system and, in other words, their ILs are always dependent on system impedance

ZL

and

Zs

, even though the mismatch between them is large.

Feed forward

While feedback filters register the noise at load side and inject the compensation signal at source side, the feed forward devices do the opposite: the sensing is at source end and the compensation at load port. For this reason, there cannot be feedforward-type implementation for type (b) and (c). Type (a) (current sensing and injecting) and type (d) (voltage sensing and injecting) can be implemented and the calculated ILs result to be:

!Type!Filter's gain (A)!Insertion Loss (IL)
(a)Current gain

Ic=A*IL

1(1-
1-A
A*ZL
ZL+Zs

)

(d)Voltage gain

Vc=A*VL

1(1-
1-A
A*Zs
Zs+ZL

)

Considering also in these two cases the condition for maximum noise reduction, i.e. maximum IL, it can be achieved when the filter's gain is equal to one. If

A1-

, it follows that

ILinfty

. It can also be noted that, if

A1+

or, generally speaking,

A>1

, the insertion loss becomes negative and thus the active filter amplifies the noise instead of reducing it.

Active vs passive

See also

Notes and References

  1. Book: Ali . Marwan . Labouré . Eric . Costa . François . 2013 15th European Conference on Power Electronics and Applications (EPE). 1–8 . 10.1109/EPE.2013.6634697 . September 2013 . Integrated hybrid EMI filter: Study and realization of the active part . 978-1-4799-0116-6 . 10951074 .
  2. Web site: Commission . IEC - International Electrotechnical . Welcome to the IEC - International Electrotechnical Commission . www.iec.ch . en.
  3. Web site: Federal Communications Commission . Federal Communications Commission . en.
  4. Web site: Radiated & Conducted Emissions Testing - EMC Testing Beginner's Guide - EMC FastPass. EMC FastPass. 2 June 2015 .
  5. Book: Takahashi . Isao . Kanazawa . Hidetoshi . Proceedings of Power Conversion Conference - PCC '97. 1 . 331–334 . 10.1109/PCCON.1997.645634 . August 1997 . Active EMI filter for switching noise of high frequency inverters . 0-7803-3823-5 . 111187865 .
  6. Web site: What's the Difference Between Passive and Active Noise Cancellation? . Electronic Design . 7 November 2017.
  7. Book: Paul . Clayton R. . Introduction to electromagnetic compatibility . 2006 . Wiley . Hoboken, NJ . 978-0-471-75500-5 . 2nd.
  8. Hashemian . Reza . Symbolic representation of network transfer functions using norator-nullator pairs - IET Journals & Magazine . IEE Journal on Electronic Circuits and Systems. 1 . 6 . 193–197 . 10.1049/ij-ecs.1977.0032 . November 1977 .
  9. Book: Poon . N.K. . 2000 IEEE 31st Annual Power Electronics Specialists Conference. Conference Proceedings (Cat. No.00CH37018). 2 . 940–945 . 10.1109/PESC.2000.879940 . June 2000 . Techniques for input ripple current cancellation: Classification and implementation . 10397/709 . 0-7803-5692-6 . 110474919 .
  10. Son . Yo-Chan . Generalization of active filters for EMI reduction and harmonics compensation. IEEE Transactions on Industry Applications. 42 . 2 . 545–551 . 10.1109/TIA.2006.870030 . March 2006 . free .
  11. Book: Amaducci. Alessandro. 2017 IEEE International Symposium on Electromagnetic Compatibility & Signal/Power Integrity (EMCSI). 612–618. 10.1109/ISEMC.2017.8077941. August 2017. Design of a wide bandwidth active filter for common mode EMI suppression in automotive systems. 978-1-5386-2229-2. 11053622 .
  12. Zhang . Dongbing . Measurement of noise source impedance of off-line converters. IEEE Transactions on Power Electronics. 15 . 5 . 820–825 . 10.1109/63.867670 . September 2000 . 2000ITPE...15..820Z .
  13. Shang . Xiaofan . A Noise Source Impedance Extraction Method for Operating SMPS Using Modified LISN and Simplified Calibration Procedure. IEEE Transactions on Power Electronics. 32 . 6 . 4132–4139 . 10.1109/TPEL.2016.2631578 . June 2017 . 2017ITPE...32.4132S . 2719236 .