SIST EN 1064:2005

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.Health informatics - Standard communication protocol - Computer-assisted electrocardiographyþXQDOQLãNRInformatique de santé - Protocole de communication standard - Electrocardiographie assistée par ordinateurMedizinische Informatik - Standardkommunikationsprotokoll - Computergestützte ElektrokardiographieTa slovenski standard je istoveten z:EN 1064:2005SIST EN 1064:2005en35.240.80ICS:SIST ENV 1064:20031DGRPHãþDSLOVENSKI
STANDARDSIST EN 1064:200501-september-2005







EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
EN 1064
February 2005 ICS 35.240.80 Supersedes ENV 1064:1993 English version
Health informatics - Standard communication protocol - Computer-assisted electrocardiography
Informatique de santé - Protocole de communication standard - Electrocardiographie assistée par ordinateur
Medizinische Informatik - Standardkommunikationsprotokoll - Computergestützte Elektrokardiographie This European Standard was approved by CEN on 17 December 2004.
CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the Central Secretariat or to any CEN member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN member into its own language and notified to the Central Secretariat has the same status as the official versions.
CEN members are the national standards bodies of Austria, Belgium, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.
EUROPEAN COMMITTEE FOR STANDARDIZATION COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG
Management Centre: rue de Stassart, 36
B-1050 Brussels © 2005 CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Members. Ref. No. EN 1064:2005: E



EN 1064:2005 (E) 2 Contents Page Foreword.4 Introduction.5 1 Scope.8 2 Normative references.8 3 Terms and definitions.8 Terms specific to this document.8 3.2 Other technical terms related to this document.10 4 Abbreviations.10 5 Definition of the data contents and format.11 5.1 General considerations.11 5.2 Specifications for the data structure.13 5.3 Pointer section – Section 0.16 5.4 Header information – Patient data / ECG acquisition data – Section 1.18 5.5 Huffman tables – Section 2.39 5.6 ECG lead definition – Section 3.41 5.7 QRS locations, reference beat subtraction zones and protected areas – Section 4.44 5.8 Encoded type 0 reference beat data – Section 5.46 5.9 Rhythm data – Section 6.49 5.10 Global measurements – Section 7.50 5.11 Storage of full text interpretive statements – Section 8.56 5.12 Storing manufacturer specific interpretive statements and data related to the overreading trail – Section 9.58 5.13 Lead measurement block – Section 10.58 5.14 Storage of the universal ECG interpretive statement codes – Section 11.61 6 Minimum requirements for encoding and compression of the ECG signal data.64 6.1 Scope and field of application.64 6.2 Introduction.64 6.3 ECG compression methodology.65 6.4 Main results from investigations on ECG data compression in the SCP-ECG project.66 6.5 Minimum requirements for ECG data compression.67 Annex A (normative)
Encoding of alphanumeric ECG data in a multilingual environment.69 A.1 General.69 A.2 Scope.69 A.3 References and definitions.70 A.4 Values.71 A.5 Control characters.72 A.6 Character set encoding.73 A.7 Language code.82 A.8 Method for handling unsupported character sets.82 A.9 Summary of the Escape sequences described in this annex for the encoding of free text in SCP-ECG.83 A.10 Examples of encoded text strings.84 Annex B (normative)
Definition of compliance with the SCP ECG standard.85 B.1 General.85 B.3 Testing/validation of SCP-ECG data format compatibility.91 B.4 Coding of SCP-ECG compliance.93



EN 1064:2005 (E) 3 Annex C (normative)
Methodology and conformance testing of the recommended ECG signal compression technique.95 C.1 General.95 C.2 Principles of “HIGH” SCP-ECG data compression.95 C.3 Equations for SCP-ECG data compression.98 C.4 Numerical examples for SCP-ECG data compression.123 C.5 Test set of ECGs for conformance testing.128 Annex D (informative)
Definition of a minimum set of control and query messages for the interchange of ECG data.130 D.1 General.130 D.2 Message formats.130 D.3 State diagrams.139 D.4 Message sequence examples.142 D.5 Use of advisory messages.144 Annex E (informative)
Standard low-level ECG-Cart to host protocol.145 E.1 General.145 E.2 Data link and physical functional layers.145 E.3 Physical functional layer.145 E.4 Remote connection.146 E.5 Data link functional layer.146 Annex F (informative)
Universal ECG interpretation statements codes.158 F.1 General.158 F.2 Constraints.158 F.3 Composition of the code and general syntax rules.158 F.4 Acronyms for ECG interpretive statements.162 F.5 Overreading of measurement results.177 Annex G (informative)
Glossary.181 Bibliography.183 National and international standards.183 References from the ECG standards literature.183 Specific references with respect to ECG data compression.184



EN 1064:2005 (E) 4 Foreword This document (EN 1064:2005) has been prepared by Technical Committee CEN/TC 251 “Health informatics”, the secretariat of which is held by SIS. This European Standard shall be given the status of a national standard, either by publication of an identical text or by endorsement, at the latest by August 2005, and conflicting national standards shall be withdrawn at the latest by August 2005. This document supersedes ENV 1064:1993. According to the CEN/CENELEC Internal Regulations, the national standards organizations of the following countries are bound to implement this European Standard: Austria, Belgium, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.



EN 1064:2005 (E) 5 Introduction The electrocardiogram (ECG) is a recording of voltage changes transmitted to the body surface by electrical events in the heart muscle, providing direct evidence of cardiac rhythm and conduction, and indirect evidence of certain aspects of myocardial anatomy, blood supply and function. During its propagation to the surface, extracardiac tissues may intervene and influence the ECG. Electrocardiography has been used for many years as a key, non-invasive method in the diagnosis and early detection of coronary heart disease, which is the leading cause of mortality in Western countries. In 1993, it was estimated that more than 100 million standard ECGs are recorded yearly in the European Community (EC) for routine diagnostic and screening purposes at an estimated cost of more than 1,2 billion ECU per year. Almost all newer electrocardiographs nowadays use digital recording, interpretation and communication techniques. These stand-alone, microcomputer based machines can be connected to each other, and to larger minicomputer based management servers for long-term storage and serial comparison. To this end, various manufacturers have used different techniques. It is in the general public interest for users not to be restricted in their options by incompatible technical features and services of different systems. ECG processing is increasingly being integrated with various other data processing in health care. This evolution shall have considerable impact on the storage and communication of ECG data. There are many different end-users who for different purposes (support of patient care, management, research and education) want to obtain a copy of the signal data, of the interpretive report and/or measurement results. Being one of the very first systems for medical decision support, computerized ECG interpretation stretches from departments of cardiology in hospitals, to general practitioners in primary care and health care centers. In life-threatening acute myocardial infarction, ECGs are being used in ambulances by paramedical personnel to assess the necessity for administering thrombolytic agents, with long-distance monitoring whenever possible. To enable the exchange of information between various systems it was of utmost importance that a standard communications protocol for computer-aided electrocardiography (SCP-ECG) had to be established, as defined in this document. The primary aim of this document is to specify a data format for transferring ECG reports and data from any vendor's computerized ECG recorder to any other's vendor central ECG management system. The same standard should also allow standardized transfer of digitised ECG data and results between various computer systems. Under the standard communication protocol (SCP) the contents and format of the ECG waveform data and the measurements from ECG devices of different manufacturers are not expected to be identical. As a result, the determination of the suitability of a device and/or system for any particular application remains with the user/purchaser. The following possible uses of ECG records require special attention:  serial comparison of ECGs and interpretations;  plot formats of ECGs;  maintaining audit trail of edits;  bi-directional communication and remote query. The user is cautioned to make sure that the data contents and format of the waveform data, measurements, and the interpretive statements meet his or her specific needs. If more than one type of ECG devices and/or database management systems are interconnected, the user is also advised to verify with the manufacturers that the data from different systems are compatible with each other and with the user’s needs.



EN 1064:2005 (E) 6 In order to understand this document, the reader needs some basic understanding of electrocardiology, electrocardiography and signal processing. This document relates to the conventional recording of the electrocardiogram, i.e. the so-called standard 12-lead electrocardiogram and the vectorcardiogram (VCG). Initially, the electric connections used for recording the ECG were made to the limbs only. These connections to the right arm (RA), left arm (LA), left leg (LL) and right leg (RL) were introduced by Einthoven. The electrical variations detected by these leads are algebraically combined to form the bipolar leads I, II, and III. Lead I, for example records the difference between the voltages of the electrodes placed on the left arm and the right arm. The unipolar electrocardiographic leads (aVR, aVL, aVF and the precordial leads V1 to V6) were introduced much later, starting in 1933. In these leads, potentials are recorded at one location with respect to a level which does not vary significantly in electrical activity during cardiac contraction. The "augmented" limb lead potentials are recorded with reference to the average potential of (L+F), (R+F) and (L+R) respectively. The unipolar chest leads are recorded with reference to the average potential of (RA+RL+LL)/3 which is called the Wilson "central terminal" (CT). In vectorcardiography recordings are made of three mutually perpendicular leads, running parallel to one of the rectilinear coordinate axes of the body. The axes are the X-axis going right to left, the Y-axis with a top to bottom orientation, and the Z or front to back axis. In some research centers, so-called body surface maps are obtained by placing many (from 24 to 124 or even more) closely spaced electrodes around the torso. This document has not been designed to handle exchange of such recordings, although future extensions could be made to this end. The standard has also not been designed to exchange specialized recordings of intracardiac potentials or of the so-called Holter or other long-term ECG recordings made for monitoring cardiac rhythm. This document also does not address exercise ECG recordings. ECG computer processing can be reduced to 3 principal stages: 1) data acquisition, encoding, transmission and storage; 2) pattern recognition and feature extraction, i.e. ECG measurement; 3) diagnostic classification. In each of these stages there are important needs for standardization and quality assurance testing. The scope of the document is confined to the first of these three stages. The various data sections that shall be transmitted by means of the standard ECG communications protocol are defined in Clause 5 of this document. Minimum requirements for data encoding and compression are defined in Clause 6. The compliance categories defined in Annex B provide users and manufacturers of ECG devices and/or systems with a relatively simple codification of SCP-ECG related features and information content that may be provided by a specific device. Four Data Format Categories have been defined based on information content as in the following table:



EN 1064:2005 (E) 7 Data Format Categories for Compliance Specifications Category Data Sections Required Content Description I 0, 1, 7, 8 Demographics, global measurements and interpretation II 0, 1, 2, 3, 6, (7), (8) Demographics and ECG rhythm data III 0, 1, 2, 3, 5, (7), (8) Demographics and reference beats IV 0, 1, 2, 3, 4, 5, 6, (7), (8) Demographics, ECG rhythm data, and reference beats NOTE Parentheses (.) indicate that these data sections are optional for export. All devices stating a SCP-ECG Data Format Category import data sections 0, 1, 7, 8. All Categories may have additional sections added (e.g. 9, 10, 11). A device may export at more than one Category. Manufacturer specific data shall be optionally included only in manufacturer specific fields, bytes and data blocks that have been defined in the document. Reserved, unspecified and undefined fields, bytes or data blocks shall not be used for manufacturer specific data. For a particular device, a SCP-ECG compliance statement lists Data Format Category(ies) for export
(i.e. acquiring and making available a SCP-ECG record) and import (i.e. accepting, and making available to a user, a SCP-ECG record). A device may also state its ability to transfer (i.e. making available a SCP-ECG record without changing its data format, for example, exporting a record that was previously imported). (These terms are precisely defined in Annex B for the purpose of this document). The selection and definition of ECG specific high-level syntaxes for transfer of messages and data between host-to-hosts, such as EDIFACT or ASN.1, are beyond the scope of this document.



EN 1064:2005 (E) 8 1 Scope This document specifies the common conventions required for the cart-to-host as well as cart-to-cart interchange of specific patient data (demographic, recording, .), ECG signal data, ECG measurement and ECG interpretation results. This document specifies the content and structure of the information which is to be interchanged between digital ECG carts and computer ECG management systems, as well as other computer systems where ECG data can be stored. 2 Normative references The following referenced documents are indispensable for the application 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/IEC 646, Information technology - ISO 7-bit coded character set for information interchange ISO/IEC 2022:1994, Information technology - Character code structure and extension techniques ISO/IEC 8859 (all parts), Information technology - 8-bit single-byte coded graphic character sets ISO/IEC 10646, Information technology -- Universal Multiple-Octet Coded Character Set (UCS)
GB 2312-80, Code of Chinese Graphic Character Set for Information Interchange - Primary Set JIS X 0201-1976, Code for Information Interchange JIS X 0208-1997, Code of the Japanese Graphic Character Set for Information Interchange JIS X 0212-1990, Code of the Supplementary Japanese Graphic Character Set for Information Interchange 3 Terms and definitions For the purposes of this document, the following terms and definitions apply. 3.1 Terms specific to this document 3.1.1 acquiring cardiograph cardiograph recording the original ECG signal 3.1.2 bimodal compression use of low pass filtering and sample decimation outside of a protected zone containing the QRS complex, with no decimation or filtering within the protected zone, is called bimodal compression, and is indicated by 5.9.3 byte 6 3.1.3 confirming process whereby a trained and experienced cardiologist reviews the computer-generated (or overread) interpretation of an ECG in order to confirm the computer-generated (or overread) interpretation or to make the final changes to the interpretation text. The confirmed ECG is the final clinically acceptable version for diagnosis and treatment



EN 1064:2005 (E) 9 3.1.4 CSE Project project supported by DG XII of the European Commission aiming at the development of Common Standards for (Quantitative) Electrocardiography 3.1.5 downsampling factor downsampling (or decimation) factor gives the reduction of samples in data sections where the sampling rate is reduced with reference to the original sampling rate. NOTE This applies for bimodal data compression. For example original sampling rate 500 S/s (which is equivalent to a sample interval of 2 ms) is reduced to 125 S/s (which is equivalent to a sample interval of 8 ms). The downsampling factor is than 4 3.1.6 interpretive device device (cart, computer) analyzing the ECG signal 3.1.7 message textual body of information 3.1.8 overreading process whereby a cardiologist or a cardiology fellow reviews the computer-generated interpretation of an ECG in order to verify the accuracy or to make changes to the interpretation text NOTE An overread ECG is generally not the final clinically acceptable version for diagnosis and treatment. Usually, the overreading process precedes the confirming process. 3.1.9 record entire data file which has to be transmitted, including the ECG data and associated information, such as patient identification, demographic and other clinical data 3.1.10 reference beat reference/representative ECG cycle computed through any (but not specified) algorithm comprising the P, QRS and the ST-T waves 3.1.11 residual data remaining original ECG data after "proper" subtraction of the reference beat. The adjective "proper" refers to accurate beat alignment 3.1.12 rhythm data full original ECG data, or the decompressed and reconstructed ECG data at reduced resolution NOTE Rhythm data is typically 10 s in length. 3.1.13 section aggregate of data elements related to one aspect of the electrocardiographic recording, measurement or interpretation



EN 1064:2005 (E) 10 3.1.14 universal statement codes ECG interpretation codes described in Annex F of this document 3.2 Other technical terms related to this document See glossary in Annex G. 4 Abbreviations AAMI American Association for the Advancement of Medical Instrumentation AC Alternating Current AHA American Heart Association AIM Advanced Informatics for Medicine Programs of the European Commission Directorate General XIII ANSI American National Standards Institute ASCII American Standard Code for Information Interchange ASN.1 Abstract Syntax Notation One AVM Amplitude Value Multiplier (see 5.8.3) BS Backspace (control character) CCITT International Telegraph and Telephone Consultative Committee CEN Comité Européen de Normalisation - European Committee for Standardisation CR Carriage Return (control character) CRC Cyclic Redundancy Check CSE
Common Standards for Quantitative Electrocardiography DG Directorate General (of the European Commission) EC European Community ECG
Electrocardiogram ECU European Currency Unit EDIFACT Electronic Data Interchange for Administration, Commerce and Transport EN
Europäische Norm (European Standard) ENV Europäische Norm Vorausgabe (European Pre-standard) ESC Escape (control character) FF Form Feed (control character) HT Horizontal Tab (control character)



EN 1064:2005 (E) 11 ICD International Classification of Diseases ID Identification IEC International Electrotechnical Commission IEEE Institute of Electrical and Electronic Engineers IMIA International Medical Informatics Association ISO International Organization for Standardisation JIS Japanese Industrial Standard LF Line Feed (control character) LSB Least significant bit MSB Most significant bit RMS Root Mean Square SCP Standard Communications Protocol SCP-ECG Standard Communications Protocol for Computerized Electrocardiography TC Technical Committee VCG Vectorcardiogram VT Vertical Tab (control character) 5 Definition of the data contents and format 5.1 General considerations 5.1.1
The data record which is to be interchanged shall be divided into different sections. The contents and format of each of these sections are defined in this document. 5.1.2
All text data (character strings) shall comply to the limited conformance requirements of ISO/IEC 2022, described in Annex A. Latin-1 (ISO/IEC 8859-1) shall be the default character set. 5.1.3
All character strings shall be NULL terminated (not part of ISO/IEC 2022). 5.1.4
For all signed binary values 2's-complement coding shall be applied. 5.1.5
All single and multiple byte binary values are regarded as unsigned integers, if not otherwise specified.



EN 1064:2005 (E) 12 5.1.6
Binary values spanning more than 1 byte shall be transmitted in ascending order of significance (the least significant byte is transmitted first, the most significant byte last). 5.1.7
Consecutive bytes are numbered from left to right (starting with 1). Bits of a byte are numbered from right to left (0 = LSB, 7 = MSB). 5.1.8
The first byte in the record (i.e. the first byte of the Checksum) is defined as Byte 1. 5.1.9
ECG samples are indexed and numbered starting with sample number 1. Sample index 0 is not used in the present document. The sample index is a ones-based 16-bit index. The first sample starts at time 0. The second sample is at time (0 + 2) ms in case
...