33.040.60 – Powerline telecommunications – PDF Standards Store

CAN/CSA-T515-97 (R2003):1997 Edition

Tue, 05 Nov 2024 14:40:45 +0000

Telecommunications - Telephone Terminal Equipment - Acoustic and Magnetic Field Requirements for Handset Telephones for Use by the Hard of Hearing

Published By	Publication Date	Number of Pages
CSA	1997	28

CAN/CSA-T515-F97:2000 Edition

Tue, 05 Nov 2024 14:40:45 +0000

Télécommunications - Matériel téléphonique - Exigences relatives aux champs acoustique et magnétique pour les postes téléphoniques à combiné pour les malentendants

Published By	Publication Date	Number of Pages
CSA	2000-02-25	26

CAN/CSA-C22.2 NO. 225-M90:1990 Edition

Tue, 05 Nov 2024 14:16:21 +0000

Telecommunications Equipment

Published By	Publication Date	Number of Pages
CSA	1990-01-01	114

BS IEC SRD 63152-2:2022:2023 Edition

Sun, 20 Oct 2024 06:20:39 +0000

PDF Catalog

PDF Pages	PDF Title
2	undefined
4	Blank Page
5	CONTENTS
8	FOREWORD
10	INTRODUCTION Figures Figure 1 – Impact of power outage in traffic
11	Figure 2 – Design flow image of ECP and ECS
13	1 Scope 2 Normative references 3 Terms and definitions
14	4 Overview of electricity continuity plan (ECP) and electricity continuity system (ECS) based on IEC 63152 4.1 Necessity of electricity continuity
15	Figure 3 – Examples of hazards that can strike cities
16	4.2 Countermeasures to disasters
17	4.3 Implementation of disaster preparedness 4.4 Planning, design and introduction of ECP & ECS Figure 4 – Introduction and operation process of ECP & ECS
18	4.5 Operation of ECP & ECS 5 Design guideline for ECP & ECS 5.1 Design flow of ECP & ECS
19	5.2 ECP & ECS creation by using use case template 5.2.1 Short use case template for city service continuity Figure 5 – Design flow diagram of ECP & ECS
20	Tables Table 1 – Short use case template for city service continuity
21	5.2.2 The first step: conceptual design Figure 6 – Short description in the template
22	5.2.3 The second step: basic design
24	Figure 7 – Complete description in the template
25	Figure 8 – Diagram(s) of use case and actors in the template
26	5.2.4 The third step: detailed design – Management timetable of ECP & ECS Figure 9 – Derivation of management timetable of ECP & ECS
27	Table 2 – Relationship of interoperability layers to ECP or ECS
28	5.2.5 The final step: detailed design completion – Specifications of ECP & ECS
29	Figure 10 – Basic model of ECP & ECS and its configuration Figure 11 – Basic model of ECP & ECS – internal configuration
30	5.2.6 Useful information for ECP development
31	5.3 ECP & ECS creation example 5.3.1 System configuration (example) – Community centre and public shelter Figure 12 – System configuration of a community centre and public shelter
32	5.3.2 The first step: conceptual design 5.3.3 The second step: basic design Figure 13 – Narrative of use case “Short description”
33	Figure 14 – Narrative of use case – Preparedness for disaster phase Figure 15 – Narrative of use case – Disaster strike phase
34	Figure 16 – Narrative of use case – Response phase Figure 17 – Narrative of use case – Recovery phase Figure 18 – Narrative of use case – Review for next preparation phase
35	Figure 19 – Diagram(s) of use case and actors list
36	Table 3 – Use case using the template
38	5.3.4 The third step: detailed design – Management timetable of ECP & ECS
39	Figure 20 – ECP & ECS management timetable (top half)
40	Figure 21 – ECP & ECS management timetable (bottom half)
41	5.3.5 The final step: detailed design completion – Specifications of ECP & ECS Table 4 – Summary of ECP (for Manager)
43	Table 5 – Estimation of electricity demand
44	Table 6 – Estimation of electricity source and storage
45	6 Operation guideline for ECP & ECS 6.1 Outline of ECP & ECS operation Table 7 – Summary of ECS (for Battery)
46	6.2 Normal time operation 6.3 Emergency time operation Figure 22 – Relationship of the ECP & ECS operations with the disaster phases
47	6.4 Update operation 7 Collaboration across ECP & ECS for plural city services 7.1 Collaboration between related services
48	7.2 ECP & ECS collaboration model for city services Figure 23 – Collaboration between related services on management timetables
49	7.3 Adaptation of 3D ECP & ECS collaboration model 7.3.1 Adaptation procedure of ECP & ECS collaboration model Figure 24 – ECP & ECS collaboration model for city services
50	7.3.2 Application to CSC planning Figure 25 – ECP & ECS collaboration model for CSC planning
51	Annex A (informative)Necessity of electricity continuity in a city A.1 Impacts of power outage A.2 Examples of impacts of power outage A.2.1 Life, home and buildings fields Figure A.1 – Life, home and buildings fields
52	A.2.2 Mobility, transportation and logistics fields Figure A.2 – Mobility, road traffic and logistics fields
53	A.2.3 Medical and commerce fields Figure A.3 – Public transportation, air traffic and logistics fields
54	Figure A.4 – Medical and commerce fields
55	A.2.4 Public and infrastructures fields Figure A.5 – Tourism and entertainment fields Figure A.6 – Public service fields
56	Figure A.7 – Education and public service fields
57	A.2.5 Industry and energy fields Figure A.8 – Social infrastructure fields
58	Figure A.9 – Industry fields Figure A.10 – Energy fields
59	Annex B (informative)Characteristics of the progression of disasters to be considered for planning CSC
60	Annex C (informative)Case of electricity continuity design 1:Regional disaster prevention base usinga free access passage of a railway station C.1 Summary C.2 Use case description Table C.1 – Use case description
63	C.3 ECP
64	C.4 ECS
65	Table C.2 – Summary of ECS (for EMS)
66	Bibliography

BS EN 50412-2-1:2005

Sat, 19 Oct 2024 16:36:37 +0000

Power line communication apparatus and systems used in low-voltage installations in the frequency range 1,6 MHz to 30 MHz - Residential, commercial and industrial environment - Immunity requirements

Published By	Publication Date	Number of Pages
BSI	2005	22

BSI 19/30368407 DC:2019 Edition

Sat, 19 Oct 2024 15:53:43 +0000

PDF Catalog

PDF Pages	PDF Title
3	TC210_62668_vot1e
6	1 Modification to Clause 2, Normative references 2 Modification to Clause 4, Requirement for conducted disturbances at AC mains power ports 3 Modification to Clause 5, Requirement for conducted disturbances at telecommunication/network ports 4 Modification to subclause 6.2, Specific requirements for dynamic frequency exclusion 5 Modification to Clause 7, Requirement for radiated disturbances
7	6 Modification to Clause 8, Measurement conditions for PLC ports 7 Modification to subclause 9.1, Conducted unsymmetrical disturbances 8 Modification to Annex ZZ, Coverage of Essential Requirements of EU Directives

BS EN 50561-1:2013:2015 Edition

Sat, 19 Oct 2024 15:52:41 +0000

This part of EN 50561 specifies limits and methods of measurement of radio disturbance characteristics for in-home communication apparatus that use the low-voltage power installation as the transmission medium. This part of EN 50561 applies to equipment that communicate over this medium in the frequency range 1,606 5 MHz to 30 MHz.

NOTE

Similar equipment that communicate outside this frequency range is under study and will be covered by another European Standard.

Procedures are given for the measurement of signals generated by the equipment and limits are specified for the frequency range 9 kHz to 400 Ghz. No measurement is required at frequencies where no limit is specified.

BS EN 50561-3:2016

Sat, 19 Oct 2024 15:51:47 +0000

This part of EN 50561 specifies limits and methods of measurement of radio disturbance characteristics for in-home communication apparatus that use the low voltage power installation as the transmission medium. This part of EN 50561 applies to equipment that uses frequencies including those above 30 MHz in order to communicate.

Procedures are given for the measurement of signals generated by the equipment and limits are specified within the frequency range 9 kHz to 400 GHz. No measurement is required at frequencies where no limits are specified.

The radiated emission requirements in this standard are not intended to be applicable to the intentional transmissions from a radio-transmitter as defined by the ITU, nor to any spurious emissions related to these intentional transmissions.

NOTE

The requirements defined in this standard effectively restrict the intended transmission frequencies to below 87,5 MHz.

PDF Catalog

PDF Pages	PDF Title
5	European foreword
6	1 Scope 2 Normative references 3 Terms and definitions
8	4 Compliance with this standard 5 Requirements for the frequency range below 30 MHz 5.1 Requirement for conducted disturbances at AC mains power port 5.2 Requirement for conducted disturbances at telecommunication/network port 5.3 Requirement for conducted disturbances and communications signals at PLC ports
9	6 Requirement for the frequency range above 30 MHz 6.1 Requirement for conducted disturbances and communications signals for frequencies between 30 MHz and 87,5 MHz Table 1 — Maximum unsymmetrical PLC transmit signal level injected between two phases or between phase and neutral conductors between 30 MHz and 87,5 MHz except for the frequency bands listed in Table A.1 Table 2 — Maximum conducted unsymmetrical disturbance signal level in the frequency bands listed in Table A.1 for services requiring increased protection 6.2 Requirement for conducted disturbances for frequencies between 87,5 MHz and 118 MHz Table 3 — Maximum conducted unsymmetrical disturbance signal level
10	Figure 1 — Maximum conducted disturbance signal level for frequencies between 30 and 118 MHz 6.3 Requirement for radiated disturbances for frequencies above 30 MHz 7 Measurement conditions for PLC ports 7.1 Operation conditions
11	7.2 Unsymmetrical conducted emission measurements between 30 and 118 MHz 8 Measurement Uncertainty
12	Annex A (normative) Excluded frequency ranges Table A.1 — Permanently excluded frequency ranges between 30 MHz and 87,5 MHz
13	Annex B (normative) Example of test arrangement
14	Figure B.1 — Example of a test arrangement for measuring the conducted unsymmetrical voltages of the transmitted PLC signal with example of coupling device
15	Annex C (informative) Rationale for the use of conducted and radiated measurement methods
17	Annex ZZ (informative) Relationship between this European standard and the essential requirements of Directive 2004/108/EC and Directive 1999/5/EC Table ZZ.1 — Correspondence between this European Standard and relevant Directives
19	Bibliography

BSI 15/30260663 DC:2015 Edition

Sat, 19 Oct 2024 15:51:15 +0000

PDF Catalog

PDF Pages	PDF Title
6	Foreword
7	Introduction
8	1 Scope 2 Normative references 3 Terms and definitions
10	4 Requirement for conducted disturbances at AC mains power ports 5 Requirement for conducted disturbances at telecommunication/network ports 6 Requirements for conducted disturbances and communications signals at PLC ports 6.1 General requirements
11	Table 1 — Limits for conducted disturbances
12	Table 2 — Maximum PLC transmit signal level between 1,6065 MHz and 30 MHz 6.2 Specific requirements for Dynamic Frequency Exclusion
13	Figure 1 — Minimum requirements for a dynamically excluded frequency range 6.3 Specific requirements for remote dynamic frequency inclusion
14	7 Requirement for radiated disturbances 8 Measurement conditions for PLC ports 9 Measurement methods and procedures for PLC ports 9.1 Conducted unsymmetrical disturbances
15	Figure 2 — Test arrangement for measuring the PLC port with an AMN Figure 3 — Example coupling system 9.2 Dynamic power control
16	Figure 4 — Example test equipment arrangement for measuring PLC transmit signal levels Figure 5 — Example schematic of 100 Ω to 50 Ω Balun 9.3 Cognitive frequency exclusion
17	9.4 Testing compliance with remote dynamic frequency inclusion 9.5 Conducted asymmetric disturbances
18	Figure 6 — Test arrangement for measuring the conducted asymmetric disturbances from the PLC port 10 Measurement Uncertainty
19	Annex A (normative) Excluded frequency ranges Table A.1 — Permanently excluded frequency ranges
20	Table A.2 — Permanent or dynamically excluded frequency ranges
21	Annex B (normative) Impedance Stabilization Network (ISN) for asymmetric disturbance measurements Figure B.1 — Example circuit schematic for ISN
22	Figure B.2 — Arrangement for measurement of the ISN common mode decoupling attenuation (isolation) (excluding the Coupling System)
23	Annex C (informative) Cognitive Frequency Exclusion C.1 Abbreviations C.2 PLC apparatus Broadcast Radio detection C.2.1 Overview C.2.2 Noise Floor C.2.3 Levels and Thresholds
24	C.3 Verification of the cognitive frequency exclusion implementation C.3.1 Measurement arrangement C.3.2 Spectrum Analyser Settings C.3.3 Artificial Signal Ingress C.3.4 Levels and thresholds at verification-bench C.3.4.1 Level of signal ingress C.3.4.2 Lower level of the excluded frequency range
25	C.3.5 Test procedure C.4 Test Signals
27	Annex ZZ (informative) Coverage of Essential Requirements of EC Directives
28	Bibliography