ISO 11451-5:2023

DRAFT INTERNATIONAL STANDARD
ISO/DIS 11451-5
ISO/TC 22/SC 32 Secretariat: JISC
Voting begins on: Voting terminates on:
2022-06-24 2022-09-16
Road vehicles — Vehicle test methods for electrical
disturbances from narrowband radiated electromagnetic
energy —
Part 5:
Reverberation chamber
Véhicules routiers — Méthodes d'essai d'un véhicule soumis à des perturbations électriques par
rayonnement d'énergie électromagnétique en bande étroite —
Partie 5: Chambre réverbérante
ICS: 43.040.10; 33.100.20
THIS DOCUMENT IS A DRAFT CIRCULATED
FOR COMMENT AND APPROVAL. IT IS
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NATIONAL REGULATIONS.
ISO/DIS 11451-5:2022(E)
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ISO/DIS 11451-5:2022(E)
DRAFT INTERNATIONAL STANDARD
ISO/DIS 11451-5
ISO/TC 22/SC 32 Secretariat: JISC
Voting begins on: Voting terminates on:

Road vehicles — Vehicle test methods for electrical
disturbances from narrowband radiated electromagnetic
energy —
Part 5:
Reverberation chamber
Véhicules routiers — Méthodes d'essai d'un véhicule soumis à des perturbations électriques par
rayonnement d'énergie électromagnétique en bande étroite —
Partie 5: Chambre réverbérante
ICS: 43.040.10; 33.100.20
COPYRIGHT PROTECTED DOCUMENT
THIS DOCUMENT IS A DRAFT CIRCULATED
FOR COMMENT AND APPROVAL. IT IS
© ISO 2022
THEREFORE SUBJECT TO CHANGE AND MAY
This document is circulated as received from the committee secretariat.
All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may
NOT BE REFERRED TO AS AN INTERNATIONAL
be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting on STANDARD UNTIL PUBLISHED AS SUCH.
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NATIONAL REGULATIONS.
Website: www.iso.org ISO/DIS 11451-5:2022(E)
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ii
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PROVIDE SUPPORTING DOCUMENTATION. © ISO 2022

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ISO/DIS 11451-5:2022(E)
Contents Page
Foreword .v
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Test conditions .5
5 Test location . 6
5.1 Reverberation chamber description . 6
5.2 Working volume . 6
6 Test instrumentation .7
6.1 Field generating device . 7
6.2 Field probes . 7
6.3 Stimulation and monitoring of the device under test (DUT) . 8
6.4 Optional: receiving antenna(s) and spectrum analyser . 8
6.5 Optional: vector network analyser . 9
7 Test set-up . 9
7.1 Vehicle placement . . 10
7.2 Field generating device location – Antenna constraints . 10
7.3 Vehicle test configurations . 10
7.3.1 Vehicle not connected to the power grid . 10
7.3.2 Vehicle in charging mode 1 or mode 2 (AC powered, without
communication) . 10
7.3.3 Vehicle in charging mode 3 or mode 4 (AC or DC powered, with
communication) . 14
7.3.4 Vehicle in charging mode through wireless power transmission (WPT) . 18
8 Test procedure .20
8.1 General . 20
8.2 Stirring configurations . 21
8.3 Test plan . 21
8.4 Test methods . 22
8.5 Reverb method with substitution method power control . 24
8.5.1 Reverb reference points . 24
8.5.2 Substitution method with empty chamber calibration .26
8.5.3 Substitution method with calibration including the vehicle .30
8.6 Test report . 32
Annex A (informative) Function performance status classification .33
Annex B (normative) Test level definition .34
Annex C (normative) Reverberation chamber characteristics.37
Annex D (informative) Tuned mode and stirred mode .46
Annex E (informative) TLS method .50
Annex F (informative) Cavity mode method .57
Annex G (informative) Reverb method with closed-loop power control .61
Annex H (informative) Chamber time constant method .63
Annex I (informative) VNA method .69
Annex J (informative) Measurement of total antenna efficiency η .76
Annex K (informative) Measurement of diffuse field correction factor F .79
df
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ISO/DIS 11451-5:2022(E)
Annex L (informative) Measurement of τ, Q, and ACS .82
Annex M (normative) Additional AAN(s) . .87
Bibliography .89
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ISO/DIS 11451-5:2022(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
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organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
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expressions related to conformity assessment, as well as information about ISO's adherence to
the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see
www.iso.org/iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 22, Road vehicles, Subcommittee SC 32,
Electrical and electronic components and general system aspects.
A list of all parts in the ISO 11451 series can be found on the ISO website.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
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DRAFT INTERNATIONAL STANDARD ISO/DIS 11451-5:2022(E)
Road vehicles — Vehicle test methods for electrical
disturbances from narrowband radiated electromagnetic
energy —
Part 5:
Reverberation chamber
1 Scope
This part of ISO 11451 specifies methods for testing the immunity of passenger cars and commercial
vehicles to electromagnetic disturbances, regardless of the vehicle propulsion system (e.g. spark
ignition engine, diesel engine, electric motor) using a reverberation chamber.
The electromagnetic disturbances considered are limited to narrowband electromagnetic fields.
While this standard refers specifically to passenger cars and commercial vehicles, generalized as
“vehicle(s)”, it can readily be applied to other types of vehicles.
ISO 11451-1 specifies general test conditions, definitions, practical use, and basic principles of the test
procedure.
Function performance status classification guidelines for immunity to electromagnetic radiation from
an off-vehicle radiation source are given in Annex A.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 11451-1, Road vehicles — Vehicle test methods for electrical disturbances from narrowband radiated
electromagnetic energy — Part 1: General principles and terminology
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 11451-1 and the following
apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— ISO Online browsing platform: available at https:// www .iso .org/ obp
— IEC Electropedia: available at https:// www .electropedia .org/
3.1
(mean) absorption cross section
ACS
[17]
average absorption cross section averaged over all polarizations and incident angles
1
Ad==σ σσ+ Ω (1)
()
acsa a,TE a,TM
Ω ∫∫
8π
4π
where
1
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ISO/DIS 11451-5:2022(E)
σ
is the absorption cross section for incident waves from a spatial direction averaged over
a
TE and TM waves,
σ
is the absorption cross section for incident TE waves from a spatial direction,
a,TE
σ
is the absorption cross section for incident TM waves from a spatial direction,
a,TM
Ω is the solid angle which is 4π for the full sphere (i.e. waves from all angles).

Note 1 to entry: measure for the ability of a vehicle to absorb energy in a reverberation chamber. It gives the
cross section area of an equivalent ideal absorber without any reflections or scattering, which absorbs the same
energy as the vehicle in the reverberation chamber. In contrast to the CLF, the ACS is a property of the vehicle
only and is the same for all reverberation chambers. Therefore, it allows determination of the necessary extra
power to compensate the loading effects by the vehicle without a loading factor measurement or a new chamber
characterization with vehicle.
Note 2 to entry: see Annexes H and L
3.2
antenna characterization factor
ACF
ratio of the average received power to forward power obtained in the antenna characterization of the
empty chamber characterization
Note 1 to entry: see 8.5.2
3.3
cavity mode method
method adopting chamber modes to generate the required field strength with less power for the
frequency between TLS method and LUF, typically 30-80 MHz, where the chamber has a lower mode
density
Note 1 to entry: see Annex F
3.4
chamber characterization factor
CCF
normalized average received power with the vehicle present
Note 1 to entry: see 8.5.2
3.5
chamber loading factor
CLF
ratio of the antenna characterization factor to the chamber characterization factor
Note 1 to entry: see 8.5.2
Note 2 to entry: it is a measure for the additional loading of the chamber due to the test setup including, for
example, the vehicle and the support equipment
3.6
chamber time constant
the mean time decay of the received power delay profile in a reverberation chamber
Note 1 to entry: see Annexes H and L
3.7
charging mode
mode of operation intended for charging the Rechargeable Energy Storage System (REESS)
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ISO/DIS 11451-5:2022(E)
3.7.1
charging mode 1
charging mode as defined in 6.2.1 of IEC 61851-1:2017
Note 1 to entry: in some countries, mode 1 charging can be prohibited or requires special precautions
3.7.2
charging mode 2
charging mode as defined in 6.2.2 of IEC 61851-1:2017, where the vehicle is connected to AC mains
using a charging cable, which has an Electric Vehicle Supply Equipment (EVSE) box in-line (e.g. In-Cable
Control Box / In-Cable Control and Protection Device), providing control pilot signalling between the
vehicle and the EVSE box and personal protection against electric shock
Note 1 to entry: in some countries, special restrictions have to be applied for mode 2 charging
Note 2 to entry: there is no communication with the vehicle
3.7.3
charging mode 3
charging mode as defined in 6.2.3 of IEC 61851-1:2017, where the vehicle is connected to a fixed
installation (EVSE, e.g. AC charging station, AC wallbox) providing AC power to the vehicle, with
communication between the vehicle and the EVSE (through signal/control lines and/or through wired
network lines)
3.7.4
charging mode 4
charging mode as defined in 6.2.4 of IEC 61851-1:2017, where the vehicle is connected to a fixed
installation (EVSE, e.g. DC charging station), providing DC power to the vehicle (with an off-board
charger), with communication between the vehicle and the EVSE (through signal/control lines and/or
through wired network lines)
3.8
coherence time of the reverberation chamber
time interval between two independent stirring configurations in stirred mode. The field in the
reverberation chamber conserves its statistical properties (e.g. the positions of the field maxima and
minima in the working volume) during the coherence time.
3.9
cumulative distribution function
CDF
probability that the electromagnetic field strength is less or equal to a specific value. A value of this
function can be used as levelling target (e.g. 100 V/m at CDF 0,2 means 20 % of the measured electric
field strength values are less or equal to 100 V/m and 80 % are higher than 100 V/m).
3.10
EV supply equipment
EVSE
equipment or a combination of equipment, providing dedicated functions to supply electric energy from
a fixed electrical installation or supply network to an EV for the purpose of charging
3.11
lowest usable frequency
LUF
lowest frequency for which the field uniformity requirements are met for the reverb method and at
least 12 independent stirring configurations can be achieved
Note 1 to entry: the LUF is determined in accordance with C.6 in Annex C
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ISO/DIS 11451-5:2022(E)
3.12
maximum chamber loading factor
MLF
maximum chamber loading factor for which the field uniformity has been demonstrated
Note 1 to entry: see 8.5.2
3.13
periodization
a method to define an analysis time window for the calculation of autocorrelation coefficients based on
the complete period of a periodic stirring process sequence
3.14
power delay profile
PDP
temporal behaviour of the power decay in a reverberation chamber after switch-off of the power source
3.15
quasi-tuned mode
an operating mode of a reverberation chamber where the response time of the DUT to the external field
is shorter than the coherence time of the reverberation chamber
3.16
rechargeable energy storage system
RESS
storage system that provides electric energy for electric propulsion which can be recharged
Note 1 to entry: components of the REESS may be high voltage (HV) batteries
3.17
reverberation chamber
high Q shielded room (cavity) whose boundary conditions are changed via one or several rotating tuners
or moving walls (including VIRCs with or without conductive contact to the floor) or repositioning of
the transmitting antenna(s)
Note 1 to entry: this results in a statistically uniform electromagnetic field
3.18
reverb method
usage of a reverberation chamber above LUF
3.19
stirred mode
an operating mode of a reverberation chamber where a tuner or a VIRC shaker is moved continuously
while the test is running
3.20
stirring configuration
a unique set of conditions that defines the RF environment. It might stand for a single tuner in a fixed
position as in classical reverberation chambers, it might stand for a position of a VIRC at a point in time,
for a momentary frequency in case of frequency stirring, or a transmitting antenna configuration.
3.21
stirring scheme
operating mode of a reverberation chamber that is a stirred mode or a tuned mode or a combination
thereof
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ISO/DIS 11451-5:2022(E)
3.22
support equipment
equipment associated with performing an EMC test on a vehicle including (but not all inclusive) load
simulator, charging cables, AMN(s), HV-AN(s), AAN(s), DUT monitoring equipment including fibre optic
interface modules and TV camera
3.23
TLS method
method using a TLS (similar as in ISO 11451-2) inside a reverberation chamber and extends the usage
beyond TEM-waveguide testing up to the LUF of the reverberation chamber
Note 1 to entry: see Annex E
3.24
total antenna efficiency
ratio of radiated power to forward power at antenna port, it is less than 1 or 100 % due to mismatching
and losses of the antenna (e.g. ohmic loss of metallic material and dielectric loss of insulation)
Note 1 to entry: see Annex J
3.25
tuned mode
operating mode of a reverberation chamber where the tuner is moved stepwise to fixed positions and
the test is repeated successively at each of those fixed tuner positions
3.26
tuner
large metallic reflector capable of changing the electromagnetic boundary conditions in a reverberation
chamber as it rotates or moves
Note 1 to entry: as the tuner moves, the nulls and maximums in the field change location, ensuring the vehicle is
exposed to a statistically uniform field
3.27
windowing
method to define an analysis time window for the calculation of autocorrelation coefficients based on a
part of a stirring process sequence
3.28
working volume
volume within the reverberation chamber that contains the vehicle, the support equipment, and the
receiving antenna, if used
3.29
VIRC
vibrating intrinsic reverberation chamber (a tent-like structure formed by conductive fabrics where
movements of the walls are excited e.g. by moving arms which push and pull corners or edges of the
tent)
4 Test conditions
The applicable frequency range for the reverb method is LUF to 18 000 MHz. Testing over the full
frequency range could require different field-generating devices, but this does not imply that testing of
overlapping frequency ranges is required.
NOTE The applicable frequency range is 0,01 MHz to LUF for the TLS method (see Annex E), 30 MHz to LUF
for the cavity mode method (see Annex F), and LUF to 18 000 MHz for the other reverb methods (see Annexes G,
H and I).
The user shall specify the test severity level or levels over the frequency range. Suggested test severity
levels are given in Annex A of this International Standard.
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ISO/DIS 11451-5:2022(E)
Standard test conditions are given in ISO 11451-1 for the following:
— test temperature;
— supply voltage;
— modulation;
— dwell time;
— frequency step sizes;
— definition of test severity levels;
— test signal quality.
5 Test location
5.1 Reverberation chamber description
The test shall be performed in a reverberation chamber.
The aim of using a reverberation chamber is to create statistically homogeneous and isotropic
electromagnetic fields within the working volume.
These conditions are not valid close to the ground floor in the working volume (see 5.2).
A reverberation chamber for vehicle testing consists of a shielded enclosure, one or several field
generating devices, and some mechanical apparatus to change the boundary conditions for the
electromagnetic fields. This mechanical apparatus may for example contain one or several rotating
tuners or moving walls, or may even be realized by using conductive fabrics as shielded enclosure (e.g.
a VIRC).
The chamber may contain a vehicle dynamometer, a turntable or both.
It may also contain a TLS (see Annex E) or other type of field generators (e.g. tunable monopoles, see
Annex F) as field generating device for testing from 0,01 MHz to the LUF.
The chamber may also contain one or several receiving antennas and one or more field probes.
The size, shape, and construction of the reverberation chamber can vary considerably. The minimum
size of the shielded enclosure is determined by the size of the test region needed, the size of the
field generation device or devices, the size and shape and location of the tuner or tuners, the needed
clearances between all these and the largest vehicle to be tested, and the intended LUF of the chamber.
An example of a rectangular reverberation chamber with one mechanical tuner and one field generating
antenna is shown in Figure 1.
After initial construction, the reverberation chamber shall be characterized in accordance with the
test methods intended to be used. For the reverb method, the chamber shall fulfil the field uniformity
requirements of Table C.2. The LUF of the reverberation chamber is determined during this initial
characterization. Following any major modifications, a new chamber characterization shall be carried
out again. Changes to the tuners shall be considered a major modification.
5.2 Working volume
The working volume is the volume that contains the vehicle, any support equipment and the receiving
antenna, if used. The form of the working volume shall be a cuboid.
The minimum distance between the working volume and the walls and ceiling of the shielded enclosure
or any tuner or any transmitting antenna shall be at least λ/4 at the lowest used frequency of the reverb
method.
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ISO/DIS 11451-5:2022(E)
The working volume for testing vehicles starts directly on the ground plane in order to contain the
full vehicle. Although this differs from IEC 61000-4-21 working volume definition, for the purpose of
chamber calibration, the reverb reference points described in IEC 61000-4-21 shall be used.
NOTE 1 For TLS method (see Annex E), and cavity mode method (see Annex F), the λ/4 minimum distance
requirement does not apply.
NOTE 2 More than one vehicle can be tested in one immunity test (e.g. testing of communication between
vehicles). If the distance between the vehicles is closer than λ/4 at the lowest tested frequency there could be
significant interaction between the vehicles. This may be desirable for investigating proximity effects. If the
distance between the vehicles is larger than λ/4 at the lowest tested frequency there will be scattering between
the vehicles similar to the scattering from walls etc. Therefore this test
...