Amendment 1 - Limits and methods of measurement of radio disturbance characteristics of electrical lighting and similar equipment

Grenzwerte und Messverfahren für Funkstörungen von elektrischen Beleuchtungseinrichtungen und ähnlichen Elektrogeräten

Amendement 1 - Limites et méthodes de mesure des perturbations radioélectriques produites par les appareils électriques d\'éclairage et les appareils analogues

Mejne vrednosti in metode merjenja karakteristik občutljivosti za radijske motnje električne razsvetljave in podobne opreme - Dopolnilo A1

General Information

Status
Not Published
Public Enquiry End Date
30-Jun-2023
Current Stage
4020 - Public enquire (PE) (Adopted Project)
Start Date
03-May-2023
Due Date
20-Sep-2023
Completion Date
19-Jul-2023

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Standards Content (Sample)

SLOVENSKI STANDARD
SIST EN IEC 55015:2019/oprA1:2023
01-junij-2023
Mejne vrednosti in metode merjenja karakteristik občutljivosti za radijske motnje
električne razsvetljave in podobne opreme - Dopolnilo A1
Amendment 1 - Limits and methods of measurement of radio disturbance characteristics
of electrical lighting and similar equipment
Grenzwerte und Messverfahren für Funkstörungen von elektrischen
Beleuchtungseinrichtungen und ähnlichen Elektrogeräten
Amendement 1 - Limites et méthodes de mesure des perturbations radioélectriques
produites par les appareils électriques d\'éclairage et les appareils analogues
Ta slovenski standard je istoveten z: EN IEC 55015:2019/prA1:2023
ICS:
33.100.10 Emisija Emission
SIST EN IEC 55015:2019/oprA1:2023 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN IEC 55015:2019/oprA1:2023

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SIST EN IEC 55015:2019/oprA1:2023
CIS/F/837/CDV
COMMITTEE DRAFT FOR VOTE (CDV)

PROJECT NUMBER:
CISPR 15/AMD1 ED9
DATE OF CIRCULATION: CLOSING DATE FOR VOTING:
2023-04-21 2023-07-14
SUPERSEDES DOCUMENTS:
CIS/F/821/CD, CIS/F/829A/CC

IEC CIS/F : INTERFERENCE RELATING TO HOUSEHOLD APPLIANCES TOOLS, LIGHTING EQUIPMENT AND SIMILAR APPARATUS
SECRETARIAT: SECRETARY:
Australia Ms Suba Ananth
OF INTEREST TO THE FOLLOWING COMMITTEES: PROPOSED HORIZONTAL STANDARD:

TC 34
Other TC/SCs are requested to indicate their interest, if any,
in this CDV to the secretary.
FUNCTIONS CONCERNED:
EMC ENVIRONMENT QUALITY ASSURANCE SAFETY
SUBMITTED FOR CENELEC PARALLEL VOTING NOT SUBMITTED FOR CENELEC PARALLEL VOTING
Attention IEC-CENELEC parallel voting
The attention of IEC National Committees, members of
CENELEC, is drawn to the fact that this Committee Draft for
Vote (CDV) is submitted for parallel voting.
The CENELEC members are invited to vote through the
CENELEC online voting system.

This document is still under study and subject to change. It should not be used for reference purposes.
Recipients of this document are invited to submit, with their comments, notification of
• any relevant patent rights of which they are aware and to provide supporting documentation,
• any relevant “in some countries” clauses to be included should this proposal proceed. Recipients are reminded that
the enquiry stage is the final stage for submitting "in some countries" clauses. See AC/22/2007.

TITLE:
Amendment 1 - Limits and methods of measurement of radio disturbance characteristics of electrical
lighting and similar equipment

PROPOSED STABILITY DATE: 2027

NOTE FROM TC/SC OFFICERS:


Copyright © 2023 International Electrotechnical Commission, IEC. All rights reserved. It is permitted to download this
electronic file, to make a copy and to print out the content for the sole purpose of preparing National Committee positions.
You may not copy or "mirror" the file or printed version of the document, or any part of it, for any other purpose without
permission in writing from IEC.

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SIST EN IEC 55015:2019/oprA1:2023
IEC CDV CISPR 15/A1/Ed9 © IEC 2023 – 2 – CIS/F/837/CDV
1 INTRODUCTION
2 This edition includes the following significant technical changes with respect to the previous edition:
3 a) The removal of the voltage probe method for the conducted disturbance measurement of local wired
4 port other than the electrical power supply interface of ELV lamps;
5 b) The introduction of limits and measurement methods for radiated disturbance of the enclosure port
6 in the frequency range 1 – 6 GHz;
7 c) The test set-up for the cconical metal housing for single capped lamps has been rotated;
8 d) The arrangement of cables connected to interfaces of wired network ports has been modified. Cable
9 length has been extended to 1,0 m;
10 e) Measuring arrangements for conducted disturbances for very large EUTs has been clarified.
11 f) Removal of Annex E regarding statistical methods
st
12 g) Includes agreed comments to 1 CD CIS/F/801/CD given in CIS/F/803a/CC
nd
13 h) Includes agreed comments to 2 CD CIS/F/821/CD given in CIS/F/829/CC.
14

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15 1 Scope
16 Replace the first and second paragraph with the following text:
17 This document sets out requirements for controlling the emission (radiated and conducted) of
18 radiofrequency disturbances from:
19 – lighting equipment (3.3.16), except for the types excluded in the second paragraph;
20 – the lighting part of multi-function equipment where this lighting part is a primary function;
21 NOTE 1 Examples are lighting equipment with visible-light communication.
22 – UV and IR radiation equipment for residential and non-industrial applications;
23 – simple advertising signs (see 3.3.1);
24 – decorative and entertainment lighting (see 3.3.6);
25 – emergency signs.
26
27 Excluded from the scope of this document are:
28 – components or modules intended to be built into lighting equipment and which are not user-
29 replaceable;
30 – lighting equipment intended exclusively for aircraft or airfield facilities (runways, service facilities,
31 platforms);
32 NOTE 2 However, general-purpose lighting that can be installed in many locations, including installations not related to aircraft
33 or airfield, is not excluded from the scope of CISPR 15.
34 – installations;
35 – equipment for which the electromagnetic compatibility requirements in the radio-frequency range
36 are explicitly formulated in other IEC standards, even if they incorporate a built-in lighting function.
37 NOTE 3 Examples of exclusions are:
38 – equipment with built-in lighting devices for display back lighting, scale illumination and signaling;
39 – video signs and dynamic displays (in scope of CISPR 32);
40 – range hoods, refrigerators, freezers (in scope of CISPR 14);
41 – photocopiers, projectors (in scope of CISPR 32);
42 – lighting equipment for road vehicles (in scope of CISPR 12);
43 – maritime equipment (in scope of IEC TC 18 and TC 80);
44 - lighting equipment operating in the ISM frequency bands (in scope of CISPR 11).
45
46 Replace the sixth paragraph with the following text and additional note:
47 The emission requirements in this document are not intended to be applicable to the intentional
48 transmissions from a radio transmitter as defined by the ITU including their spurious emissions.
49
50
51

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IEC CDV CISPR 15/A1/Ed9 © IEC 2023 – 4 – CIS/F/837/CDV
52 2  Normative references
53 Replace the references to CISPR 16-1-1 with the following updated reference:
54 CISPR 16-1-1:2019, Specification for radio disturbance and immunity measuring apparatus and
55 methods – Part 1-1: Radio disturbance and immunity measuring apparatus – Measuring apparatus
56 Add the following just below the CISPR 16-1-2 reference:
57 CISPR 16-1-2:2014/AMD1:2017
58 Replace the reference to CISPR 16-1-4 with the following updated reference:
59 CISPR 16-1-4:2019/AMD1:2020, Specification for radio disturbance and immunity measuring apparatus
60 and methods – Part 1-4: Radio disturbance and immunity measuring apparatus – Antennas and test
61 sites for radiated disturbance measurements
62
63 Insert the following refences to new amendments under the existing references to CISPR 16-2-3 and
64 CISPR 16-4-2 respectively:
65 CISPR 16-2-3:2016/AMD1:2019
66 CISPR 16-4-2:2011/AMD2:2018
67 Insert the following new reference just below the existing reference to CISPR TR 30-1:
68 CISPR TR 30-2:2012, Test method on electromagnetic emissions – Part 2: Electronic control gear for
69 discharge lamps excluding fluorescent lamps
70
71 Modify definitions 3.2.6 and 3.2.7 to read:
72 3.2.6
73 primary function
74 function of an equipment as specified in the instructions for use
75 3.2.7
76 secondary function
77 any function of an equipment not being essential for fulfilling the primary function as specified in the
78 instructions for use
79
80 Modify definitions 3.3.1 and 3.3.2 to the following:
81 3.3.1
82 simple advertising sign
83 unit which makes use of lighting for advertising, traffic signage, road signs or alike
84 Note 1 to entry:  Examples are neon tube advertising signs, emergency signs, inner-illuminated signs.
85 3.3.2
86 ancillary equipment
87 transducers (e.g. current probes and artificial networks) and other equipment (e.g. cables, preamplifiers,
88 attenuators, filters, adapters) connected to a measuring receiver or to the EUT and used in the
89 disturbance signal transfer between the EUT and the measuring receiver
90
91 Add a note to entry at the end of definition 3.3.3:

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92 Note 2 to entry: The emission from the associated equipment should not influence the emission of the EUT.
93
94 Replace the existing term of definition 3.3.6 with the following new term and add two new notes (reusing
95 the same definition):
96 3.3.6
97 decorative and entertainment lighting
98 equipment that emits light for atmospheric, artistic or ambiance purposes
99 Note 1 to entry:  Examples of decorative lighting include LED strip lights, rope lights, and projectors for illuminating building
100 walls or statues in coloured and/or patterned light. Usually, these types of lighting equipment are static, but they can shift
101 through various colours/patterns.
102 Note 2 to entry:  Examples of entertainment lighting include stage, theatre and sky beam lights. Usually, these types of lighting
103 equipment also include some movement, such as dynamically changing the direction of the projected light.”
104
105 Modify the definition 3.3.16 as follows (keeping the existing Note 1 to entry):
106 3.3.16
107 lighting equipment
108 device that can be used as an independent unit to illuminate a scene, objects or their surroundings so that they
109 can be seen, and modules and components designed to be used in or with such device or assembly of devices
110
111 Modify definition 3.3.20 to the following:
112 3.3.20
113 restricted ELV lamp
114 ELV lamp with specific restrictions on the type of power supply and/or the cable length that can be
115 applied to it, as specified in the instructions for use
116 Add a new definition for user replaceable:
117 3.3.24
118 User replaceable
119 Components which may be replaced by an ordinary person
120 3.5 Abbreviated terms
121 Correct the term AAN to the following:
AAN asymmetric artificial network
122 Add the term FSOATS:
FSOATS free space open area test site
123 Add the term Fc:
Fc Clock frequency
124
125 Remove the term ISN
126
127 4.3.1 Electric power supply interface
128 Add the following note below Table 1:

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129 NOTE In the US, lighting devices are classified as either a non-consumer (Class A) or consumer (Class B) device. These
130 classifications limits are similar to the Class A and Class B equipment categories in the CISPR 32:2015+A1 2019 publication.
131
132 4.3.2 Wired network interfaces other than power supply
133 In NOTE 2 replace the term ‘artificial asymmetrical network’ with ‘asymmetric artificial network’
134
135 4.4 Limits and methods for the assessment of local wired ports
136 Delete the existing third paragraph.
137 Replace the existing fifth paragraph with:
138 The limits and methods given in Table 6 shall be applied to local wired ports other than electrical power
139 supply interface of ELV lamps.
140 Delete Table 5.
141
142 Table 6 – Disturbance current limits at local wired ports: local wired ports other than electrical
143 power supply interface of ELV lamp
144 Within the table, renumber existing NOTE 1 to NOTE and delete existing NOTE 2.
145
146 4.5.2 Frequency range 9 kHz to 30 MHz
147 Replace the fifth paragraph with the following text:
148 The limits in Table 7 and Table 8 provide different options. The test report shall state which method
149 was used and which limits were applied.
150 Replace Table 7 with the following:
151 Table 7 – Maximum EUT dimension that can be used
152 for testing using LLAS with different diameters
Maximum dimension of the EUT, D Loop antenna diameter
m m
2
D ≤ 1,6
D ≤ 2,4 3
D ≤ 3,2 4
No minimum EUT dimensions are given for the 3 m and 4 m LLAS antenna systems.
However, it is recommended to apply the smallest size of the EUT.
If a small EUT is tested in a large LLAS (i.e., EUT smaller than 1,6 m tested in a 3 m
or 4 m LLAS, or EUT smaller than 2,4 m tested in a 4 m LLAS), it shall be confirmed
that the LLAS is able to detect EUT generated emissions with at least 10 dB of margin
above the measuring instrument’s noise floor.
153
154 Correct the position of Table 9; insert existing table 9 at the end of 4.5.2 directly after Table 8.
155
156 4.5.3 Frequency range 30 MHz to 1 GHz
157 Replace the second paragraph with the following text:

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158 Table 10 provides different options. The test report shall state which method was used and which limits
159 were applied.
160 Delete Table 9.
161 Insert additional sentence to table note (b) of Table 10:
b
162  The TEM-waveguide is limited to EUTs without cables attached and with a maximum size according to 6.2 of IEC 61000-4-
163 20:2010 (the largest dimension of the enclosure at 1 GHz measuring frequency is one wavelength, 300 mm at 1 GHz). The
164 results taken in a TEM waveguide are converted to field strength for comparison with OATS-based limits at 10 m distance.
165
166 Add note below Table 10:
167 NOTE In the US, lighting devices are classified as either a non-consumer (Class A) or consumer (Class B) device. These
168 classifications limits are similar to the Class A and Class B equipment categories in the CISPR 32:2015+A1 2019 publication.
169
170 Insert new clause 4.5.4 with following text:
171 4.5.4 Frequency range 1 GHz to 6 GHz
172 Radiated emission measurements in this frequency range shall be performed up to the frequency determined in
173 accordance with Table 13, based on the highest clock frequency of the EUT. However, if the clock frequencies of
174 the EUT are not known, radiated emission measurements shall be performed up to 6 GHz.
175 Table 13 – Radiated measurement highest frequency
Highest clock Highest
frequency measurement
(Fc) frequency
Fc ≤ 108 MHz 1 GHz
108 MHz < Fc ≤ 500 2 GHz
MHz
500 MHz < Fc ≤ 1 GHz 5 GHz
Fc > 1 GHz 5 × Fc up to a
maximum of 6 GHz
176
177 Radiated-field disturbance limits and measurement methods in the frequency range of 1 GHz to 6 GHz are given
178 in Table 14in terms of peak and average values of the electric field component.
179 Table 14 – Radiated emissions requirements at frequencies above 1 GHz
Frequency Range MHz Testing Method Testing Detector Limits
Distance m Type / dB(uV
bandwidth /m)
1 000 to 3 000  Average / 1 50
FSOATS 3 MHz
3 000 to 6 000 54
1 000 to 3 000 70
Peak / 1 MHz
3 000 to 6 000 74
Apply across the frequency range from 1 000 MHz to the highest required frequency of measurement derived from
Table 13.
Allowed measurement distances:1 m, 3 m, 5 m, or 10m.
Where a different measurement distance is chosen, other than the reference testing distance defined (3 m), the
limit is offset based upon the following formula:
New limit = defined limit – 20 log (measurement distance/reference distance)
An FSOATS may be a SAC/OATS with RF absorber on the RGP or a FAR, see specific details in CISPR 16-2-
3:2016
180
181 NOTE In the US, lighting devices are classified as either a non-consumer (Class A) or consumer (Class B) device. These
182 classifications limits are similar to the Class A and Class B equipment categories in the CISPR 32:2015+A1 2019 publication.
183
184 5.3.2.2 Conducted disturbance requirements for wired network interfaces other than power
185 supply

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186 In the second paragraph, replace the term ‘artificial asymmetrical network’ with ‘asymmetric artificial
187 network’
188
189 5.3.3 Conducted disturbance requirements for local wired ports
190 Replace the existing second paragraph with:
191 For local wired ports other than power supply interface of ELV lamp, the disturbance current limits given
192 in Table 6 shall be applied using the measurement method given in 8.5.2.3. The method of measurement
193 and the applicable limits for the power supply interface of ELV lamp are described in 6.4.7.
194
195 5.3.4.1 Frequency range 9 kHz to 30 MHz
196 Replace the first bullet under the first paragraph with the following:
197 – the instructions for use allows external wired interfaces connected to the EUT by single-conductor
198 cables;
199
200 Insert a new clause 5.3.4.3 as follows:
201 5.3.4.3 Frequency range 1 GHz to 6 GHz
202 The EUT shall be tested for radiated emissions in the range 1 GHz to 6 GHz in accordance with Table
203 14.
204
205 5.3.6 Interfaces that can be categorised as multiple types of ports
206 Modify the example given in clause 5.3.6. to the following:
207 EXAMPLE A power-over-Ethernet can be identified as both a wired network port (Ethernet-connection) and a local-wired port
208 (DC power supply). For the wired network port (Ethernet-connection), the limits in either Table 2 or Table 3 would apply. For
209 the local-wired port (DC power supply) the limits in Table 6 apply. In this case, the disturbance current limits of Table 3 and
210 Table 6 are the same. In this example, the limits for either type of port are basically the same. Broadband over power and
211 powerline communication are other examples where the interface in question can be categorized as different kinds of wired
212 network ports (4.3).
213
214 6.3.2 Requirements for rope lights
215 Add reference to new Table 14 in first paragraph:
216 Rope lights with active switching electronic components shall comply with the disturbance voltage limits
217 at mains terminals given in Table 1 and with the radiated disturbance limits given in Table 8 or Table 9
218 if applicable, and in Table 10 and Table 14 if applicable.
219

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220 6.4 Modules
221 Replace the title of this subclause with:
222 6.4 Components and modules
223
224 6.4.1 General
225 Replace all instances of ‘module’ (or ‘modules’) with ‘component or module’ (or ‘components or modules’)
226 Replace the fifth paragraph with the following text:
227 The host or the type of luminaire and associated circuits which are suitable and representative for use
228 with the component or module as specified in the instructions for use. This shall be based on analysing
229 various possible typical applications for the specific component or module such that the selected host
230 is representative of typical use in terms of mitigation of disturbances from the component or module in
231 question.
232
233 6.4.3 Internal modules
234 Replace the second paragraph with the following text:
235 The host, that includes the module as EUT, is tested as a luminaire in accordance with
236 Clause B.6 (Figure B.1b) and Clause C.4(Figure C.4) or CDNE setup according
237 CISPR 16-2-1:2014/AMD1:2017. Examples of the host (reference luminaire) can be found in CISPR TR
238 30-1:2012 and CISPR TR 30-2:2012.
239 NOTE The host/reference luminaire is considered as the EUT and therefore the limitation of the CDNE method to EUTs having
240 not more than two cables (CISPR 16-2-1:2014 + AMD1:2017 clause 9.1 3rd paragraph item c) is applicable to the host and not
241 to the internal module.
242 Modify clause 6.4.5 as follows:
243 6.4.5 Single capped self-ballasted lamps
244 Single capped self-ballasted lamps shall comply with the disturbance voltage limits at electric power
245 supply interface given in Table 1 and with the radiated disturbance limits given in Table 8 or Table 9 if
246 applicable, and in Table 10 and Table 14 if applicable.
247 The setup and test arrangements for single capped self-ballasted lamps are specified in Clause A.1.
248
249 6.4.6 Double-capped self-ballasted lamps, double-capped lamp adapters, doublecapped semi-
250 luminaires and double-capped retrofit lamps used in fluorescent lamp luminaires
251 Add reference to new Table 14 in first paragraph:
252 Double-capped self-ballasted lamps, double-capped lamp adapters, double-capped semiluminaires and
253 double-capped retrofit lamps used in fluorescent lamp luminaires shall comply with the electric power supply
254 interface voltage limits given in Table 1 and with the radiated disturbance limits given in Table 8 or Table 9 if
255 applicable, and in Table 10 and Table 14 if applicable.
256
257 6.4.7 ELV lamps
258 Add reference to new Table 14 in first bullet point of the first paragraph:
259 ELV lamps shall comply with one of the following requirements:
260 a) Non-restricted (see 3.3.20) extra-low voltage (ELV) lamps, intended for connection to symmetrical ELV
261 networks, shall comply with the conducted disturbance voltages of local wired ports of Table 4 at the ELV
262 interface, measured in accordance with the method specified A.5.1, and with the radiated disturbance limits of
263 Table 8 or Table 9 if applicable, and in Table 10 and Table 14 if applicable, measured in accordance with the
264 method specified in A.5.2.
265 Add reference to new Table 14 in first bullet point of the first paragraph:

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266 b) Restricted ELV lamps (see 3.3.20) shall comply with the mains disturbance voltage limits of Table 1,
267 measured in accordance with the method specified A.5.1, and with the radiated disturbance limits of Table 8 or
268 Table 9 if applicable, and in Table 10 and Table 14 if applicable, measured in accordance with the method
269 specified in A.5.2.
270
271 6.4.10 Replaceable starters for fluorescent lamps
272 Modify the second sentence in the first paragraph to read:
273 The instructions for use shall specify the type of luminaire and associated circuit(s), which are suitable
274 for use with the starter.
275
276 7.1 General
277 Replace the second paragraph with:
278 The EUT is to be tested under normal operating conditions, for example, as given in IEC 60598-1 for
279 luminaires.
280
281 7.3 Supply voltage and frequency
282 Replace the entire clause with the following text:
283 During the tests, the EUT shall be operated at the rated voltage specified for the equipment. The supply
284 voltage shall be within ± 2% of the selected nominal test voltage.
285 For single-phase equipment with a rated voltage range of:
286 − 100 V to 127 V, testing shall be carried out at one nominal voltage within this range; the recommended
287 test voltage is 120 V;
288 − 200 V to 240 V, testing shall be carried out at one nominal voltage within this range; the recommended
289 test voltage is 230 V;
290 − 100 V to 240 V, testing shall be carried out at one nominal voltage within the range 100 V to 127 V
291 (recommended value is 120 V), and at one nominal voltage within the range 200 V to 240 V
292 (recommended value is 230 V).
293 However, if the lighting equipment is intended for a specific region, it may be tested only at the
294 corresponding nominal voltage in the applicable voltage range for that region. This decision shall be
295 recorded in the test report.
296 Multi-phase equipment shall be tested applying the same principles set-out above.
297 For three-phase equipment with a rated voltage range of:
298 − 200 V to 240 V, testing shall be carried out at one nominal voltage within this range; the recommended
299 test voltage is 220 V;
300 − 380 V to 450 V, testing shall be carried out at one nominal voltage within this range; the recommended
301 test voltage is 400 V.
302 EUTs that can be operated from either an AC or DC supply shall be measured in both conditions.
303 If the rated frequency range includes 50 Hz and 60 Hz, a measurement at either 50 Hz or at 60 Hz shall
304 be performed. The emissions at the other mains frequency are then covered by this measurement.
305
306 7.5 Operating modes
307 Replace the entire clause with the following:

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308 If the EUT is capable of being used in different operating modes e.g. flashing, running illumination,
309 communication by light modulation, colour shifting, emergency, charging etc., then measurements shall
310 be performed in the worst-case mode of operation, i.e. the mode of operation with the highest emission
311 relative to the limit.
312 NOTE Multiple charge regimes can be used by some battery technologies during charging, i.e. fast, trickle, stand by, PWM
313 etc. for applications in torches, emergency lighting, etc.
314
315 The worst case shall be found either by pre-scanning every mode of operation over at least one
316 repetition interval of the specific mode, or by using the setting(s) that are expected to produce the
317 highest amplitude emissions relative to the limit.
318
319 NOTE 1 Maximum electromagnetic disturbances can often be captured by operating all channels of a LED driver that are
320 needed to create different colours and/or correlated-colour-temperatures (CCT). The number of channels applied
321 depends on the LED-driver/LED-light-source architecture.
322 NOTE 2 Maximum electromagnetic disturbances can often be captured by selecting a white colour and/or a CCT setting in
323 the middle of the specified CCT range.
324 EXAMPLE Colour variation and CCT variation can be achieved using a 5-channel LED driver powering three LED strings for
325 colour (RGB) setting and two cool white and warm white LED strings for CCT setting. Hence, in case the lighting equipment
326 under test is capable to operate at different colours and/or CCTs, a white colour and/or a single CCT in the middle of the
327 specified CCT range can be selected.
328
329 The reasons for the selection shall be given in the test report.
330
331 7.6 Ambient conditions
332 Replace the first paragraph with the following text:
333 Measurements shall be carried out in normal laboratory conditions. The ambient temperature shall be
334 within the range from 15° C to 30° C or within the range specified in the instructions for use if more
335 restricted.
336
337 7.7.2 Ageing times
338 Replace the first sentence of the second paragraph with:
339 Unless otherwise stated in this document or specified in the instructions for use, the following ageing
340 times shall be applied:
341
342 7.8 Stabilization times
343 Replace the text of this paragraph with:
344 Prior to a measurement, the EUT including the light source(s) or lamp(s) that is (are) part of the EUT
345 shall be operated until stabilization has been reached. Unless otherwise stated in this document or
346 specified in the instructions for use, the following stabilization time shall be applied:
347 – 30 min for EUTs that include gas discharge technologies
348 – 1 min for EUTs that do not include gas discharge technologies.
349
350 7.9.1 General
351 In the second sentence, replace ‘by the manufacturer.’ with ‘in the instruction for use.’
352

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353 7.9.4 Load
354 In the second bullet point, replace ‘by the manufacturer’ with ‘in the instruction for use’
355 8.2 Measurement instrumentation and methods
356 Replace Table 11 with the following new table:
357 Table 11 – Overview of standardized conducted disturbance measurement methods
Interface Limits Frequency range Reference
CISPR 16-1-1:2015 (receiver)
Electric power supply CISPR 16-1-2:2014 (AMN)
Table 1 9 kHz to 30 MHz
interface
CISPR 16-2-1:2014/AMD1:2017
(measurement method)
CISPR 16-1-1:2015 (receiver)
CISPR 16-1-2:2014 (AAN, artificial
Table 2 150 kHz to 30 MHz network, voltage probe, CP, CVP)
Wired network interfaces
CISPR 16-2-1:2014/AMD1:2017 and 8.4
other than power supply
(measurement method)
interface (e.g., for
communication or data
CISPR 16-1-1:2015 (receiver)
transfer)
CISPR 16-1-2:2014 (current probe)
a
Table 3 150 kHz to 30 MHz
CISPR 16-2-1:2014/AMD1:2017 and 8.4
(measurement method)
CISPR 16-1-1:2015 (receiver)
Local wired port –
Table 1 or CISPR 16-1-2:2014 (AMN)
electrical power supply 9 kHz to 30 MHz
Table 4
CISPR 16-2-1:2014/AMD1:2017 and A.5.1
interface of ELV lamps
(measurement method)
CISPR 16-1-1:2015 (receiver)
CISPR 16-1-2:2014 (current probe)
Local wired port – other
than the electrical power
CISPR 16-2-1:2014/AMD1:2017 and
Table 6 150 kHz to 30 MHz
supply interface of ELV
8.5.2.3 (measurement method)
lamps
a
 Depending on the EUT port
...

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