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IEEE 11073 20101 Application Profile – Association Control Function

IEEE 11073 20101 Application Profile – Association Control Function. Dan Smith, dssmith@westhealth.org Harry McKee, hlmckee@westhealth.org. Agenda. Scope Assumptions Approach Sample Advantages Disadvantages Removed fields Issues Next Steps. Scope Summary:.

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IEEE 11073 20101 Application Profile – Association Control Function

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  1. IEEE 11073 20101 Application Profile – Association Control Function Dan Smith, dssmith@westhealth.org Harry McKee, hlmckee@westhealth.org

  2. Agenda • Scope • Assumptions • Approach • Sample • Advantages • Disadvantages • Removed fields • Issues • Next Steps

  3. Scope Summary: • Define compatible set of ASN.1 messages for both 20101 & 20601 • Allow all data to be communicated using the MDER Encoding Rules • Support the existence of multiple-protocol managers that support both POC & PHD devices

  4. Assumptions • The CNS (20401) proposal will identify unique network paths (ie. TCP port) for each standard (classic 20101, 20601 & proposed harmonized) • Existing PHD devices properly verify the fields in existing 20601 messages (ie data-proto-id) before using the data received

  5. General Approach • Adopt the 20601 approach to messaging • Move away from ACSE Standard • Add new data fields to the 20601 structures to capture needed 20101 data • Implement a “NULL” Presentation & Session Layer – aka remove their functionality from association.

  6. AARQ ASN.1 MdapAssociationInformation ::= SEQUENCE { user-info MDSEUserInfo } MDSEUserInfo ::= SEQUENCE { protocolVersion ProtocolVersion, nomenclatureVersion NomenclatureVersion, functionalUnits FunctionalUnits, systemType SystemType, startupMode StartupMode, optionList AttributeList, supportedAProfiles AttributeList } AarqApdu ::= SEQUENCE { assoc-version AssociationVersion, data-proto-list DataProtoList } AssociationVersion ::= BITS-32 { assoc-version1 (0) -- association protocol version 1 } DataProtoList ::= SEQUENCE OF DataProto DataProto ::= SEQUENCE { data-proto-id DataProtoId, data-proto-info ANY DEFINED BY data-proto-id } DataProtoId ::= INT-U16 { data-proto-id-empty (0), data-proto-id-20101 (20101), data-proto-id-20601 (20601), data-proto-id-external (65535) }

  7. Advantages to this approach • POC & PHD devices will share the same messaging structure at a high level • All message data is encoded using MDER • POC-specific data is captured with the new MDAPAssociationInformation field • Simplifies Implementation • Allows managers to more easily support multiple association styles*. * See disadvantage page

  8. Disadvantages to this approach • May require separate port for “classic” ACSE messages vs. “new” style messages • due to overlap between MDAP-XT session layer & PHD-defined AARQ (0xe2) • Moves away from standardized association towards a custom solution for medical devices

  9. Removed Fields Proposal removes application-context-name (AARQ/AARE) AARQ-apdu ::= [APPLICATION 0] IMPLICIT SEQUENCE { protocol-version [0] IMPLICIT BIT STRING {version1(0)} DEFAULT {version1}, application-context-name [1] Application-context-name, user-information [30] IMPLICIT Association-information }

  10. Removed Fields Proposal removes the “Associate-source-diagnostic” field AARE-apdu ::= [APPLICATION 1] IMPLICIT SEQUENCE { protocol-version [0] IMPLICIT BIT STRING {version1(0)} DEFAULT {version1}, application-context-name [1] Application-context-name, result [2] Associate-result, Result-source-diagnostic [3] Associate-source-diagnostic, user-information [30] IMPLICIT Association-information } Associate-source-diagnostic ::= CHOICE { acse-service-user [1] INTEGER { null(0), no-reason-given(1), application-context-name-not-supported (2), }, acse-service-provider [2] INTEGER { null(0), no-reason-given(1), no-common-acse-version(2) } }

  11. Removed Fields POC & PHD aborts are slightly different ABRT-apdu ::= [APPLICATION 4] IMPLICIT SEQUENCE { abort-source [0] IMPLICIT ABRT-source } ABRT-source ::= INTEGER { acse-service-user(0), acse-service-provider(1) } AbrtApdu ::= SEQUENCE { reason Abort-reason } Abort-reason ::= INT-U16 { undefined(0), buffer-overflow(1), response-timeout(2), configuration-timeout(3) }

  12. Open Issues • Is there a need to support other encoding rules (such as BER?) • MDER-only makes implementations easier • Must be able to encode all data properly • Must account for all applications of this protocol • Is anything lost by being MDER-only?

  13. Open Issues Adding in a “fast-association” component • Match PHD's config-id based “fast association” feature • Reduce amount of data transferred during connection process • POC order of association (initial message sent from manager) makes things more difficult • Possibly could be solved with a second AARQ message

  14. Next Steps • Write up a full proposal • Discuss it on a periodic web-ex • Finalize proposal & vote – hopefully at F2F in Jan.

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