Electromagnetic reverberation chamber

An electromagnetic reverberation chamber (also known as a reverb chamber (RVC) or mode-stirred chamber (MSC)) is an environment for electromagnetic compatibility (EMC) testing and other electromagnetic investigations. Electromagnetic reverberation chambers have been introduced first by H.A. Mendes in 1968.[1] A reverberation chamber is screened room with a minimum of absorption of electromagnetic energy. Due to the low absorption, very high field strength can be achieved with moderate input power. A reverberation chamber is a cavity resonator with a high Q factor. Thus, the spatial distribution of the electrical and magnetic field strengths is strongly inhomogeneous (standing waves). To reduce this inhomogeneity, one or more tuners (stirrers) are used. A tuner is a construction with large metallic reflectors that can be moved to different orientations in order to achieve different boundary conditions. The Lowest Usable Frequency (LUF) of a reverberation chamber depends on the size of the chamber and the design of the tuner. Small chambers have a higher LUF than large chambers.

A look inside the (large) Reverberation Chamber at the Otto-von-Guericke-University Magdeburg, Germany. On the left side is the vertical Mode Stirrer (or Tuner), that changes the electromagnetic boundaries to ensure a (statistically) homogeneous field distribution.

The concept of a reverberation chamber is comparable to a microwave oven.

Glossary/notation

edit

Preface

edit

The notation is mainly the same as in the IEC standard 61000-4-21.[2] For statistic quantities like mean and maximal values, a more explicit notation is used in order to emphasize the used domain. Here, spatial domain (subscript  ) means that quantities are taken for different chamber positions, and ensemble domain (subscript  ) refers to different boundary or excitation conditions (e.g. tuner positions).

General

edit

Statistics

edit
  •  : spatial mean of   for   objects (positions in space).
  •  : ensemble mean of   for   objects (boundaries, i.e. tuner positions).
  •  : equivalent to  . Thist is the expected value in statistics.
  •  : spatial maximum of   for   objects (positions in space).
  •  : ensemble maximum of   for   objects (boundaries, i.e. tuner positions).
  •  : equivalent to  .
  •  : max to mean ratio in the spatial domain.
  •  : max to mean ratio in the ensemble domain.

Theory

edit

Cavity resonator

edit

A reverberation chamber is cavity resonator—usually a screened room—that is operated in the overmoded region. To understand what that means we have to investigate cavity resonators briefly.

For rectangular cavities, the resonance frequencies (or eigenfrequencies, or natural frequencies)   are given by

 

where   is the speed of light,  ,   and   are the cavity's length, width and height, and  ,  ,   are non-negative integers (at most one of those can be zero).

With that equation, the number of modes with an eigenfrequency less than a given limit  ,  , can be counted. This results in a stepwise function. In principle, two modes—a transversal electric mode   and a transversal magnetic mode  —exist for each eigenfrequency.

The fields at the chamber position   are given by

  • for the TM modes ( )
  
  
  
  
  
  
  • for the TE modes ( )
  
  
  
  
  

Due to the boundary conditions for the E- and H field, some modes do not exist. The restrictions are:[3]

  • For TM modes: m and n can not be zero, p can be zero
  • For TE modes: m or n can be zero (but not both can be zero), p can not be zero

A smooth approximation of  ,  , is given by

 

The leading term is proportional to the chamber volume and to the third power of the frequency. This term is identical to Weyl's formula.

 
Comparison of the exact and the smoothed number of modes for the Large Magdeburg Reverberation Chamber.

Based on   the mode density   is given by

 

An important quantity is the number of modes in a certain frequency interval  ,  , that is given by

 

Quality factor

edit

The Quality Factor (or Q Factor) is an important quantity for all resonant systems. Generally, the Q factor is defined by   where the maximum and the average are taken over one cycle, and   is the angular frequency.

The factor Q of the TE and TM modes can be calculated from the fields. The stored energy   is given by

 

The loss occurs in the metallic walls. If the wall's electrical conductivity is   and its permeability is  , the surface resistance   is

 

where   is the skin depth of the wall material.

The losses   are calculated according to

 

For a rectangular cavity follows[4]

  • for TE modes:
  
 
  • for TM modes:
 
 

Using the Q values of the individual modes, an averaged Composite Quality Factor   can be derived:[5]    

  includes only losses due to the finite conductivity of the chamber walls and is therefore an upper limit. Other losses are dielectric losses e.g. in antenna support structures, losses due to wall coatings, and leakage losses. For the lower frequency range the dominant loss is due to the antenna used to couple energy to the room (transmitting antenna, Tx) and to monitor the fields in the chamber (receiving antenna, Rx). This antenna loss   is given by   where   is the number of antenna in the chamber.

The quality factor including all losses is the harmonic sum of the factors for all single loss processes:

 

Resulting from the finite quality factor the eigenmodes are broaden in frequency, i.e. a mode can be excited even if the operating frequency does not exactly match the eigenfrequency. Therefore, more eigenmodes are exited for a given frequency at the same time.

The Q-bandwidth   is a measure of the frequency bandwidth over which the modes in a reverberation chamber are correlated. The   of a reverberation chamber can be calculated using the following:

 

Using the formula   the number of modes excited within   results to

 

Related to the chamber quality factor is the chamber time constant   by

 

That is the time constant of the free energy relaxation of the chamber's field (exponential decay) if the input power is switched off.

See also

edit

Notes

edit
  1. ^ Mendes, H.A.: A new approach to electromagnetic field-strength measurements in shielded enclosures., Wescon Tech. Papers, Los Angeles, CA., August, 1968.
  2. ^ IEC 61000-4-21: Electromagnetic compatibility (EMC) – Part 4-21: Testing and measurement techniques – Reverberation chamber test methods, Ed. 2.0, January, 2011. ([1])
  3. ^ Cheng, D.K.: Field and Wave Electromagnetics, Addison-Wesley Publishing Company Inc., Edition 2, 1998. ISBN 0-201-52820-7
  4. ^ Chang, K.: Handbook of Microwave and Optical Components, Volume 1, John Wiley & Sons Inc., 1989. ISBN 0-471-61366-5.
  5. ^ Liu, B.H., Chang, D.C., Ma, M.T.: Eigenmodes and the Composite Quality Factor of a Reverberating Chamber, NBS Technical Note 1066, National Bureau of Standards, Boulder, CO., August 1983.

References

edit
  • Crawford, M.L.; Koepke, G.H.: Design, Evaluation, and Use of a Reverberation Chamber for Performing Electromagnetic Susceptibility/Vulnerability Measurements, NBS Technical Note 1092, National Bureau od Standards, Boulder, CO, April, 1986.
  • Ladbury, J.M.; Koepke, G.H.: Reverberation chamber relationships: corrections and improvements or three wrongs can (almost) make a right, Electromagnetic Compatibility, 1999 IEEE International Symposium on, Volume 1, 1–6, 2–6 August 1999.