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Defines the basic properties of every data value. This
is an abstract type, meaning that no value can be just
a data value without belonging to any concrete type.
Every concrete type is a specialization of this
general abstract DataValue type.
An exceptional value expressing missing information
and possibly the reason why the information is missing.
The Boolean type stands for the values of two-valued logic.
A Boolean value can be either true or
false, or, as any other value may be NULL.
The Boolean type stands for the values of two-valued logic.
A Boolean value can be either true or
false, or, as any other value may be NULL.
The BooleanNonNull type is used where a Boolean cannot
have a null value. A Boolean value can be either
true or false.
The BooleanNonNull type is used where a Boolean cannot
have a null value. A Boolean value can be either
true or false.
The BooleanNonNull type is used where a Boolean cannot
have a null value. A Boolean value can be either
true or false.
Binary data is a raw block of bits. Binary data is a
protected type that MUST not be used outside the data
type specification.
Specifies the representation of the binary data that
is the content of the binary data value.
Binary data is a raw block of bits. Binary data is a
protected type that MUST not be used outside the data
type specification.
Data that is primarily intended for human interpretation
or for further machine processing is outside the scope of
HL7. This includes unformatted or formatted written language,
multimedia data, or structured information as defined by a
different standard (e.g., XML-signatures.) Instead of the
data itself, an ED may contain
only a reference (see TEL.) Note
that the ST data type is a
specialization of the ED data type
when the ED media type is text/plain.
A telecommunication address (TEL), such as a URL
for HTTP or FTP, which will resolve to precisely
the same binary data that could as well have been
provided as inline data.
Identifies the type of the encapsulated data and
identifies a method to interpret or render the data.
For character based information the language property
specifies the human language of the text.
Indicates whether the raw byte data is compressed,
and what compression algorithm was used.
The integrity check is a short binary value representing
a cryptographically strong checksum that is calculated
over the binary data. The purpose of this property, when
communicated with a reference is for anyone to validate
later whether the reference still resolved to the same
data that the reference resolved to when the encapsulated
data value with reference was created.
Specifies the algorithm used to compute the
integrityCheck value.
A thumbnail is an abbreviated rendition of the full
data. A thumbnail requires significantly fewer
resources than the full data, while still maintaining
some distinctive similarity with the full data. A
thumbnail is typically used with by-reference
encapsulated data. It allows a user to select data
more efficiently before actually downloading through
the reference.
The character string data type stands for text data,
primarily intended for machine processing (e.g.,
sorting, querying, indexing, etc.) Used for names,
symbols, and formal expressions.
The character string data type stands for text data,
primarily intended for machine processing (e.g.,
sorting, querying, indexing, etc.) Used for names,
symbols, and formal expressions.
Text content is only allowed in non-NULL values.
Coded data in its simplest form, consists of a code.
The code system and code system version is fixed by
the context in which the CS value occurs. CS is used
for coded attributes that have a single HL7-defined
value set.
A concept descriptor represents any kind of concept usually
by giving a code defined in a code system. A concept
descriptor can contain the original text or phrase that
served as the basis of the coding and one or more
translations into different coding systems. A concept
descriptor can also contain qualifiers to describe, e.g.,
the concept of a "left foot" as a postcoordinated term built
from the primary code "FOOT" and the qualifier "LEFT".
In exceptional cases, the concept descriptor need not
contain a code but only the original text describing
that concept.
The text or phrase used as the basis for the coding.
Specifies additional codes that increase the
specificity of the primary code.
A set of other concept descriptors that translate
this concept descriptor into other code systems.
The plain code symbol defined by the code system.
For example, "784.0" is the code symbol of the ICD-9
code "784.0" for headache.
Specifies the code system that defines the code.
A common name of the coding system.
If applicable, a version descriptor defined
specifically for the given code system.
A name or title for the code, under which the sending
system shows the code value to its users.
Coded data, consists of a coded value (CV)
and, optionally, coded value(s) from other coding systems
that identify the same concept. Used when alternative
codes may exist.
The text or phrase used as the basis for the coding.
A set of other concept descriptors that translate
this concept descriptor into other code systems.
The plain code symbol defined by the code system.
For example, "784.0" is the code symbol of the ICD-9
code "784.0" for headache.
Specifies the code system that defines the code.
A common name of the coding system.
If applicable, a version descriptor defined
specifically for the given code system.
A name or title for the code, under which the sending
system shows the code value to its users.
Coded data, consists of a code, display name, code system,
and original text. Used when a single code value must be sent.
The text or phrase used as the basis for the coding.
The plain code symbol defined by the code system.
For example, "784.0" is the code symbol of the ICD-9
code "784.0" for headache.
Specifies the code system that defines the code.
A common name of the coding system.
If applicable, a version descriptor defined
specifically for the given code system.
A name or title for the code, under which the sending
system shows the code value to its users.
Coded data, consists of a code, display name, code system,
and original text. Used when a single code value must be sent.
The plain code symbol defined by the code system.
For example, "784.0" is the code symbol of the ICD-9
code "784.0" for headache.
Coded data, where the domain from which the codeset comes
is ordered. The Coded Ordinal data type adds semantics
related to ordering so that models that make use of such
domains may introduce model elements that involve statements
about the order of the terms in a domain.
A concept qualifier code with optionally named role.
Both qualifier role and value codes must be defined by
the coding system. For example, if SNOMED RT defines a
concept "leg", a role relation "has-laterality", and
another concept "left", the concept role relation allows
to add the qualifier "has-laterality: left" to a primary
code "leg" to construct the meaning "left leg".
A value component is required or else the
code role is NULL.
Specifies the manner in which the concept role value
contributes to the meaning of a code phrase. For
example, if SNOMED RT defines a concept "leg", a role
relation "has-laterality", and another concept "left",
the concept role relation allows to add the qualifier
"has-laterality: left" to a primary code "leg" to
construct the meaning "left leg". In this example
"has-laterality" is the CR.name.
The concept that modifies the primary code of a code
phrase through the role relation. For example, if
SNOMED RT defines a concept "leg", a role relation
"has-laterality", and another concept "left", the
concept role relation allows adding the qualifier
"has-laterality: left" to a primary code "leg" to
construct the meaning "left leg". In this example
"left" is the CR.value.
Indicates if the sense of the role name is inverted.
This can be used in cases where the underlying code
system defines inversion but does not provide reciprocal
pairs of role names. By default, inverted is false.
A ST that optionally may have a code attached.
The text must always be present if a code is present. The
code is often a local code.
The plain code symbol defined by the code system.
For example, "784.0" is the code symbol of the ICD-9
code "784.0" for headache.
Specifies the code system that defines the code.
A common name of the coding system.
If applicable, a version descriptor defined
specifically for the given code system.
A name or title for the code, under which the sending
system shows the code value to its users.
A unique identifier string is a character string which
identifies an object in a globally unique and timeless
manner. The allowable formats and values and procedures
of this data type are strictly controlled by HL7. At this
time, user-assigned identifiers may be certain character
representations of ISO Object Identifiers (OID) and DCE
Universally Unique Identifiers (UUID). HL7 also reserves
the right to assign other forms of UIDs, such as mnemonic
identifiers for code systems.
A globally unique string representing an ISO Object Identifier
(OID) in a form that consists only of non-negative numbers with
no leading zeros and dots (e.g., "2.16.840.1.113883.3.1").
According to ISO, OIDs are paths in a tree structure, with the
left-most number representing the root and the right-most number
representing a leaf.
A DCE Universal Unique Identifier is a globally unique
string consisting of 5 groups of upper- or lower-case
hexadecimal digits having 8, 4, 4, 4, and 12 places
respectively. UUIDs are assigned using Ethernet MAC
addresses, the point in time of creation and some random
components. This mix is believed to generate sufficiently
unique identifiers without any organizational policy for
identifier assignment (in fact this piggy-backs on the
organization of MAC address assignment.)
HL7 reserved identifiers are strings consisting only of
(US-ASCII) letters, digits and hyphens, where the first
character must be a letter. HL7 may assign these reserved
identifiers as mnemonic identifiers for major concepts of
interest to HL7.
An identifier that uniquely identifies a thing or object.
Examples are object identifier for HL7 RIM objects,
medical record number, order id, service catalog item id,
Vehicle Identification Number (VIN), etc. Instance
identifiers are defined based on ISO object identifiers.
A root component is required or else the II value is NULL.
A unique identifier that guarantees the global uniqueness
of the instance identifier. The root alone may be the
entire instance identifier.
A character string as a unique identifier within the
scope of the identifier root.
A human readable name or mnemonic for the assigning
authority. This name may be provided solely for the
convenience of unaided humans interpreting an II value
and can have no computational meaning. Note: no
automated processing must depend on the assigning
authority name to be present in any form.
Specifies if the identifier is intended for human
display and data entry (displayable = true) as
opposed to pure machine interoperation (displayable
= false).
A telecommunications address specified according to
Internet standard RFC 1738
[http://www.ietf.org/rfc/rfc1738.txt]. The
URL specifies the protocol and the contact point defined
by that protocol for the resource. Notable uses of the
telecommunication address data type are for telephone and
telefax numbers, e-mail addresses, Hypertext references,
FTP references, etc.
A telecommunications address specified according to
Internet standard RFC 1738
[http://www.ietf.org/rfc/rfc1738.txt]. The
URL specifies the protocol and the contact point defined
by that protocol for the resource. Notable uses of the
telecommunication address data type are for telephone and
telefax numbers, e-mail addresses, Hypertext references,
FTP references, etc.
A quantity specifying a point on the axis of natural time.
A point in time is most often represented as a calendar
expression.
A quantity specifying a point on the axis of natural time.
A point in time is most often represented as a calendar
expression.
PQ
A telephone number (voice or fax), e-mail address, or
other locator for a resource (information or service)
mediated by telecommunication equipment. The address
is specified as a Universal Resource Locator (URL)
qualified by time specification and use codes that help
in deciding which address to use for a given time and
purpose.
Specifies the periods of time during which the
telecommunication address can be used. For a
telephone number, this can indicate the time of day
in which the party can be reached on that telephone.
For a web address, it may specify a time range in
which the web content is promised to be available
under the given address.
One or more codes advising a system or user which
telecommunication address in a set of like addresses
to select for a given telecommunication need.
A character string that may have a type-tag signifying its
role in the address. Typical parts that exist in about
every address are street, house number, or post box,
postal code, city, country but other roles may be defined
regionally, nationally, or on an enterprise level (e.g. in
military addresses). Addresses are usually broken up into
lines, which are indicated by special line-breaking
delimiter elements (e.g., DEL).
Specifies whether an address part names the street,
city, country, postal code, post box, etc. If the type
is NULL the address part is unclassified and would
simply appear on an address label as is.
Mailing and home or office addresses. A sequence of
address parts, such as street or post office Box, city,
postal code, country, etc.
A General Timing Specification (GTS) specifying the
periods of time during which the address can be used.
This is used to specify different addresses for
different times of the year or to refer to historical
addresses.
A set of codes advising a system or user which address
in a set of like addresses to select for a given purpose.
A boolean value specifying whether the order of the
address parts is known or not. While the address parts
are always a Sequence, the order in which they are
presented may or may not be known. Where this matters, the
isNotOrdered property can be used to convey this
information.
A character string token representing a part of a name.
May have a type code signifying the role of the part in
the whole entity name, and a qualifier code for more detail
about the name part type. Typical name parts for person
names are given names, and family names, titles, etc.
Indicates whether the name part is a given name, family
name, prefix, suffix, etc.
The qualifier is a set of codes each of which specifies
a certain subcategory of the name part in addition to
the main name part type. For example, a given name may
be flagged as a nickname, a family name may be a
pseudonym or a name of public records.
A name for a person, organization, place or thing. A
sequence of name parts, such as given name or family
name, prefix, suffix, etc. Examples for entity name
values are "Jim Bob Walton, Jr.", "Health Level Seven,
Inc.", "Lake Tahoe", etc. An entity name may be as simple
as a character string or may consist of several entity name
parts, such as, "Jim", "Bob", "Walton", and "Jr.", "Health
Level Seven" and "Inc.", "Lake" and "Tahoe".
An interval of time specifying the time during which
the name is or was used for the entity. This
accomodates the fact that people change names for
people, places and things.
A set of codes advising a system or user which name
in a set of like names to select for a given purpose.
A name without specific use code might be a default
name useful for any purpose, but a name with a specific
use code would be preferred for that respective purpose.
A name for a person. A sequence of name parts, such as
given name or family name, prefix, suffix, etc. PN differs
from EN because the qualifier type cannot include LS
(Legal Status).
A name for an organization. A sequence of name parts.
An interval of time specifying the time during which
the name is or was used for the entity. This
accomodates the fact that people change names for
people, places and things.
A set of codes advising a system or user which name
in a set of like names to select for a given purpose.
A name without specific use code might be a default
name useful for any purpose, but a name with a specific
use code would be preferred for that respective purpose.
A restriction of entity name that is effectively a simple string used
for a simple name for things and places.
An interval of time specifying the time during which
the name is or was used for the entity. This
accomodates the fact that people change names for
people, places and things.
The quantity data type is an abstract generalization
for all data types (1) whose value set has an order
relation (less-or-equal) and (2) where difference is
defined in all of the data type's totally ordered value
subsets. The quantity type abstraction is needed in
defining certain other types, such as the interval and
the probability distribution.
QTY
Integer numbers (-1,0,1,2, 100, 3398129, etc.) are precise
numbers that are results of counting and enumerating.
Integer numbers are discrete, the set of integers is
infinite but countable. No arbitrary limit is imposed on
the range of integer numbers. Two NULL flavors are
defined for the positive and negative infinity.
Integer numbers (-1,0,1,2, 100, 3398129, etc.) are precise
numbers that are results of counting and enumerating.
Integer numbers are discrete, the set of integers is
infinite but countable. No arbitrary limit is imposed on
the range of integer numbers. Two NULL flavors are
defined for the positive and negative infinity.
INT
Fractional numbers. Typically used whenever quantities
are measured, estimated, or computed from other real
numbers. The typical representation is decimal, where
the number of significant decimal digits is known as the
precision. Real numbers are needed beyond integers
whenever quantities of the real world are measured,
estimated, or computed from other real numbers. The term
"Real number" in this specification is used to mean
that fractional values are covered without necessarily
implying the full set of the mathematical real numbers.
Fractional numbers. Typically used whenever quantities
are measured, estimated, or computed from other real
numbers. The typical representation is decimal, where
the number of significant decimal digits is known as the
precision. Real numbers are needed beyond integers
whenever quantities of the real world are measured,
estimated, or computed from other real numbers. The term
"Real number" in this specification is used to mean
that fractional values are covered without necessarily
implying the full set of the mathematical real numbers.
REAL
A representation of a physical quantity in a unit from
any code system. Used to show alternative representation
for a physical quantity.
The magnitude of the measurement value in terms of
the unit specified in the code.
A dimensioned quantity expressing the result of a
measurement act.
PQ
An alternative representation of the same physical
quantity expressed in a different unit, of a different
unit code system and possibly with a different value.
The magnitude of the quantity measured in terms of
the unit.
The unit of measure specified in the Unified Code for
Units of Measure (UCUM)
[http://aurora.rg.iupui.edu/UCUM].
A monetary amount is a quantity expressing the amount of
money in some currency. Currencies are the units in which
monetary amounts are denominated in different economic
regions. While the monetary amount is a single kind of
quantity (money) the exchange rates between the different
units are variable. This is the principle difference
between physical quantity and monetary amounts, and the
reason why currency units are not physical units.
MO
The magnitude of the monetary amount in terms of the
currency unit.
The currency unit as defined in ISO 4217.
A quantity constructed as the quotient of a numerator
quantity divided by a denominator quantity. Common
factors in the numerator and denominator are not
automatically cancelled out. RTO supports titers
(e.g., "1:128") and other quantities produced by
laboratories that truly represent ratios. Ratios are
not simply "structured numerics", particularly blood
pressure measurements (e.g. "120/60") are not ratios.
In many cases REAL should be used instead
of RTO.
The probability assigned to the value, a decimal number
between 0 (very uncertain) and 1 (certain).
A code for a common (periodical) activity of daily
living based on which the event related periodic
interval is specified.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
RTO_QTY_QTY
The quantity that is being divided in the ratio. The
default is the integer number 1 (one).
The quantity that devides the numerator in the ratio.
The default is the integer number 1 (one).
The denominator must not be zero.
Note: because this type is defined as an extension of SXCM_T,
all of the attributes and elements accepted for T are also
accepted by this definition. However, they are NOT allowed
by the normative description of this type. Unfortunately,
we cannot write a general purpose schematron contraints to
provide that extra validation, thus applications must be
aware that instance (fragments) that pass validation with
this might might still not be legal.
A prototype of the repeating interval specifying the
duration of each occurrence and anchors the periodic
interval sequence at a certain point in time.
A time duration specifying a reciprocal measure of
the frequency at which the periodic interval repeats.
Specifies if and how the repetitions are aligned to
the cycles of the underlying calendar (e.g., to
distinguish every 30 days from "the 5th of every
month".) A non-aligned periodic interval recurs
independently from the calendar. An aligned periodic
interval is synchronized with the calendar.
Indicates whether the exact timing is up to the party
executing the schedule (e.g., to distinguish "every 8
hours" from "3 times a day".)
Note: because this type is defined as an extension of SXCM_T,
all of the attributes and elements accepted for T are also
accepted by this definition. However, they are NOT allowed
by the normative description of this type. Unfortunately,
we cannot write a general purpose schematron contraints to
provide that extra validation, thus applications must be
aware that instance (fragments) that pass validation with
this might might still not be legal.
A code for a common (periodical) activity of daily
living based on which the event related periodic
interval is specified.
An interval of elapsed time (duration, not absolute
point in time) that marks the offsets for the
beginning, width and end of the event-related periodic
interval measured from the time each such event
actually occurred.
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
PPD_PQ
The primary measure of variance/uncertainty of the
value (the square root of the sum of the squares of
the differences between all data points and the mean).
The standard deviation is used to normalize the data
for computing the distribution function. Applications
that cannot deal with probability distributions can
still get an idea about the confidence level by looking
at the standard deviation.
A code specifying the type of probability distribution.
Possible values are as shown in the attached table.
The NULL value (unknown) for the type code indicates
that the probability distribution type is unknown. In
that case, the standard deviation has the meaning of an
informal guess.
PPD_PQ
The primary measure of variance/uncertainty of the
value (the square root of the sum of the squares of
the differences between all data points and the mean).
The standard deviation is used to normalize the data
for computing the distribution function. Applications
that cannot deal with probability distributions can
still get an idea about the confidence level by looking
at the standard deviation.
A code specifying the type of probability distribution.
Possible values are as shown in the attached table.
The NULL value (unknown) for the type code indicates
that the probability distribution type is unknown. In
that case, the standard deviation has the meaning of an
informal guess.
Note: because this type is defined as an extension of SXCM_T,
all of the attributes and elements accepted for T are also
accepted by this definition. However, they are NOT allowed
by the normative description of this type. Unfortunately,
we cannot write a general purpose schematron contraints to
provide that extra validation, thus applications must be
aware that instance (fragments) that pass validation with
this might might still not be legal.
A prototype of the repeating interval specifying the
duration of each occurrence and anchors the periodic
interval sequence at a certain point in time.
A time duration specifying a reciprocal measure of
the frequency at which the periodic interval repeats.
Specifies if and how the repetitions are aligned to
the cycles of the underlying calendar (e.g., to
distinguish every 30 days from "the 5th of every
month".) A non-aligned periodic interval recurs
independently from the calendar. An aligned periodic
interval is synchronized with the calendar.
Indicates whether the exact timing is up to the party
executing the schedule (e.g., to distinguish "every 8
hours" from "3 times a day".)
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
Note: because this type is defined as an extension of SXCM_T,
all of the attributes and elements accepted for T are also
accepted by this definition. However, they are NOT allowed
by the normative description of this type. Unfortunately,
we cannot write a general purpose schematron contraints to
provide that extra validation, thus applications must be
aware that instance (fragments) that pass validation with
this might might still not be legal.
A code for a common (periodical) activity of daily
living based on which the event related periodic
interval is specified.
An interval of elapsed time (duration, not absolute
point in time) that marks the offsets for the
beginning, width and end of the event-related periodic
interval measured from the time each such event
actually occurred.
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
A code specifying whether the set component is included
(union) or excluded (set-difference) from the set, or
other set operations with the current set component and
the set as constructed from the representation stream
up to the current point.
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
The low limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
The high limit of the interval.
The arithmetic mean of the interval (low plus high
divided by 2). The purpose of distinguishing the center
as a semantic property is for conversions of intervals
from and to point values.
The difference between high and low boundary. The
purpose of distinguishing a width property is to
handle all cases of incomplete information
symmetrically. In any interval representation only
two of the three properties high, low, and width need
to be stated and the third can be derived.
Specifies whether the limit is included in the
interval (interval is closed) or excluded from the
interval (interval is open).
The time interval during which the given information
was, is, or is expected to be valid. The interval can
be open or closed, as well as infinite or undefined on
either side.
The time interval during which the given information
was, is, or is expected to be valid. The interval can
be open or closed, as well as infinite or undefined on
either side.
The quantity in which the bag item occurs in its containing bag.
The quantity in which the bag item occurs in its containing bag.
The origin of the list item value scale, i.e., the
physical quantity that a zero-digit in the sequence
would represent.
A ratio-scale quantity that is factored out of the
digit sequence.
A sequence of raw digits for the sample values. This is
typically the raw output of an A/D converter.
The origin of the list item value scale, i.e., the
physical quantity that a zero-digit in the sequence
would represent.
A ratio-scale quantity that is factored out of the
digit sequence.
A sequence of raw digits for the sample values. This is
typically the raw output of an A/D converter.
This is the start-value of the generated list.
The difference between one value and its previous
different value. For example, to generate the sequence
(1; 4; 7; 10; 13; ...) the increment is 3; likewise to
generate the sequence (1; 1; 4; 4; 7; 7; 10; 10; 13;
13; ...) the increment is also 3.
If non-NULL, specifies that the sequence alternates,
i.e., after this many increments, the sequence item
values roll over to start from the initial sequence
item value. For example, the sequence (1; 2; 3; 1; 2;
3; 1; 2; 3; ...) has period 3; also the sequence
(1; 1; 2; 2; 3; 3; 1; 1; 2; 2; 3; 3; ...) has period
3 too.
The integer by which the index for the sequence is
divided, effectively the number of times the sequence
generates the same sequence item value before
incrementing to the next sequence item value. For
example, to generate the sequence (1; 1; 1; 2; 2; 2; 3; 3;
3; ...) the denominator is 3.
This is the start-value of the generated list.
The difference between one value and its previous
different value. For example, to generate the sequence
(1; 4; 7; 10; 13; ...) the increment is 3; likewise to
generate the sequence (1; 1; 4; 4; 7; 7; 10; 10; 13;
13; ...) the increment is also 3.
If non-NULL, specifies that the sequence alternates,
i.e., after this many increments, the sequence item
values roll over to start from the initial sequence
item value. For example, the sequence (1; 2; 3; 1; 2;
3; 1; 2; 3; ...) has period 3; also the sequence
(1; 1; 2; 2; 3; 3; 1; 1; 2; 2; 3; 3; ...) has period
3 too.
The integer by which the index for the sequence is
divided, effectively the number of times the sequence
generates the same sequence item value before
incrementing to the next sequence item value. For
example, to generate the sequence (1; 1; 1; 2; 2; 2; 3; 3;
3; ...) the denominator is 3.
RTO_PQ_PQ
The quantity that is being divided in the ratio. The
default is the integer number 1 (one).
The quantity that devides the numerator in the ratio.
The default is the integer number 1 (one).
The denominator must not be zero.
RTO_MO_PQ
The quantity that is being divided in the ratio. The
default is the integer number 1 (one).
The quantity that devides the numerator in the ratio.
The default is the integer number 1 (one).
The denominator must not be zero.
The probability assigned to the value, a decimal number
between 0 (very uncertain) and 1 (certain).
The following types are used internally in data typesvocSet: D10642 (C-0-D10642-cpt)specDomain: V10651 (C-0-D10642-V10651-cpt)specDomain: V17887 (C-0-D10642-V17887-cpt)specDomain: V14822 (C-0-D10642-V14822-cpt)specDomain: V10649 (C-0-D10642-V14822-V10649-cpt)specDomain: V10648 (C-0-D10642-V14822-V10648-cpt)vocSet: D10684 (C-0-D10684-cpt)abstDomain: V10701 (C-0-D10684-V10701-cpt)abstDomain: V10685 (C-0-D10684-V10685-cpt)abstDomain: V10758 (C-0-D10684-V10685-V10758-cpt)vocSet: D10620 (C-0-D10620-cpt)vocSet: D17388 (C-0-D17388-cpt)vocSet: D15888 (C-0-D15888-cpt)abstDomain: V15889 (C-0-D15888-V15889-cpt)abstDomain: V10659 (C-0-D15888-V10659-cpt)abstDomain: V10666 (C-0-D15888-V10659-V10666-cpt)abstDomain: V10660 (C-0-D15888-V10659-V10660-cpt)abstDomain: V10671 (C-0-D15888-V10659-V10671-cpt)vocSet: D15880 (C-0-D15880-cpt)abstDomain: V15881 (C-0-D15880-V15881-cpt)abstDomain: V10653 (C-0-D15880-V10653-cpt)vocSet: D15913 (C-0-D15913-cpt)abstDomain: V15914 (C-0-D15913-V15914-cpt)abstDomain: V200 (C-0-D15913-V200-cpt)specDomain: V19619 (C-0-D15913-V200-V19619-cpt)specDomain: V19591 (C-0-D15913-V200-V19591-cpt)vocSet: D17385 (C-0-D17385-cpt)vocSet: D14824 (C-0-D14824-cpt)abstDomain: V14832 (C-0-D14824-V14832-cpt)abstDomain: V14835 (C-0-D14824-V14835-cpt)abstDomain: V14839 (C-0-D14824-V14839-cpt)abstDomain: V14848 (C-0-D14824-V14848-cpt)abstDomain: V14850 (C-0-D14824-V14850-cpt)abstDomain: V14825 (C-0-D14824-V14825-cpt)abstDomain: V14845 (C-0-D14824-V14845-cpt)vocSet: D10637 (C-0-D10637-cpt)abstDomain: V17860 (C-0-D10637-V17860-cpt)vocSet: D10747 (C-0-D10747-cpt)vocSet: D17416 (C-0-D17416-cpt)vocSet: D201 (C-0-D201-cpt)abstDomain: V190 (C-0-D201-V190-cpt)specDomain: V10628 (C-0-D201-V190-V10628-cpt)specDomain: V19613 (C-0-D201-V190-V19613-cpt)vocSet: D10706 (C-0-D10706-cpt)vocSet: D14866 (C-0-D14866-cpt)The following types are used for structural RIM attributesvocSet: D11527 (C-0-D11527-cpt)specDomain: V13856 (C-0-D11527-V13856-cpt)specDomain: V14002 (C-0-D11527-V13856-V14002-cpt)specDomain: V14003 (C-0-D11527-V13856-V14002-V14003-cpt)specDomain: V11534 (C-0-D11527-V13856-V11534-cpt)specDomain: V11529 (C-0-D11527-V13856-V11529-cpt)specDomain: V19580 (C-0-D11527-V13856-V11529-V19580-cpt)specDomain: V11530 (C-0-D11527-V13856-V11529-V19580-V11530-cpt)specDomain: V18875 (C-0-D11527-V13856-V11529-V18875-cpt)abstDomain: V17893 (C-0-D11527-V13856-V11529-V17893-cpt)specDomain: V11535 (C-0-D11527-V13856-V11535-cpt)abstDomain: V19445 (C-0-D11527-V13856-V19445-cpt)specDomain: V19442 (C-0-D11527-V13856-V19445-V19442-cpt)specDomain: V18938 (C-0-D11527-V13856-V19445-V19442-V18938-cpt)specDomain: V13948 (C-0-D11527-V13856-V19445-V19442-V18938-V13948-cpt)specDomain: V19444 (C-0-D11527-V13856-V19445-V19444-cpt)specDomain: V19441 (C-0-D11527-V13856-V19445-V19441-cpt)specDomain: V19443 (C-0-D11527-V13856-V19445-V19443-cpt)abstDomain: V19604 (C-0-D11527-V13856-V19604-cpt)abstDomain: V19603 (C-0-D11527-V13856-V19603-cpt)vocSet: D10196 (C-0-D10196-cpt)abstDomain: V10197 (C-0-D10196-V10197-cpt)abstDomain: V10202 (C-0-D10196-V10202-cpt)abstDomain: V19375 (C-0-D10196-V19375-cpt)abstDomain: V19371 (C-0-D10196-V19371-cpt)abstDomain: V18943 (C-0-D10196-V18943-cpt)abstDomain: V18965 (C-0-D10196-V18965-cpt)abstDomain: V16742 (C-0-D10196-V16742-cpt)specDomain: V10199 (C-0-D10196-V16742-V10199-cpt)abstDomain: V16735 (C-0-D10196-V16735-cpt)abstDomain: V16730 (C-0-D10196-V16730-cpt)abstDomain: V19372 (C-0-D10196-V19372-cpt)abstDomain: V19458 (C-0-D10196-V19458-cpt)abstDomain: V19459 (C-0-D10196-V19459-cpt)abstDomain: V19460 (C-0-D10196-V19460-cpt)abstDomain: V19461 (C-0-D10196-V19461-cpt)vocSet: D10317 (C-0-D10317-cpt)abstDomain: V18977 (C-0-D10317-V18977-cpt)specDomain: V19376 (C-0-D10317-V18977-V19376-cpt)specDomain: V10318 (C-0-D10317-V10318-cpt)specDomain: V10324 (C-0-D10317-V10324-cpt)abstDomain: V19625 (C-0-D10317-V10324-V19625-cpt)specDomain: V10329 (C-0-D10317-V10329-cpt)abstDomain: V14900 (C-0-D10317-V10329-V14900-cpt)abstDomain: V19618 (C-0-D10317-V10329-V14900-V19618-cpt)abstDomain: V19617 (C-0-D10317-V10329-V14900-V19617-cpt)abstDomain: V19590 (C-0-D10317-V10329-V19590-cpt)specDomain: V10330 (C-0-D10317-V10329-V10330-cpt)specDomain: V10337 (C-0-D10317-V10337-cpt)specDomain: V18660 (C-0-D10317-V10337-V18660-cpt)specDomain: V10342 (C-0-D10317-V10337-V10342-cpt)specDomain: V10338 (C-0-D10317-V10337-V10338-cpt)abstDomain: V11610 (C-0-D10317-V11610-cpt)abstDomain: V19446 (C-0-D10317-V19446-cpt)abstDomain: V19447 (C-0-D10317-V19447-cpt)abstDomain: V19000 (C-0-D10317-V19000-cpt)abstDomain: V19005 (C-0-D10317-V19005-cpt)abstDomain: V19562 (C-0-D10317-V19562-cpt)vocSet: D16031 (C-0-D16031-cpt)vocSet: D16478 (C-0-D16478-cpt)abstDomain: V18934 (C-0-D16478-V18934-cpt)abstDomain: V18937 (C-0-D16478-V18937-cpt)abstDomain: V18935 (C-0-D16478-V18935-cpt)abstDomain: V18936 (C-0-D16478-V18936-cpt)vocSet: D10882 (C-0-D10882-cpt)specDomain: V13922 (C-0-D10882-V13922-cpt)specDomain: V10884 (C-0-D10882-V13922-V10884-cpt)specDomain: V11621 (C-0-D10882-V13922-V10884-V11621-cpt)specDomain: V10883 (C-0-D10882-V13922-V10883-cpt)specDomain: V13934 (C-0-D10882-V13922-V10883-V13934-cpt)specDomain: V11622 (C-0-D10882-V13922-V10883-V13934-V11622-cpt)specDomain: V11623 (C-0-D10882-V13922-V10883-V13934-V11623-cpt)specDomain: V10892 (C-0-D10882-V13922-V10892-cpt)abstDomain: V19462 (C-0-D10882-V19462-cpt)abstDomain: V19463 (C-0-D10882-V19463-cpt)specDomain: V10889 (C-0-D10882-V19463-V10889-cpt)specDomain: V19455 (C-0-D10882-V19463-V10889-V19455-cpt)vocSet: D10878 (C-0-D10878-cpt)specDomain: V10879 (C-0-D10878-V10879-cpt)abstDomain: V19647 (C-0-D10878-V19647-cpt)vocSet: D10609 (C-0-D10609-cpt)specDomain: V10610 (C-0-D10609-V10610-cpt)specDomain: V10616 (C-0-D10609-V10610-V10616-cpt)specDomain: V10612 (C-0-D10609-V10610-V10612-cpt)specDomain: V10614 (C-0-D10609-V10610-V10612-V10614-cpt)vocSet: D10901 (C-0-D10901-cpt)abstDomain: V10247 (C-0-D10901-V10247-cpt)specDomain: V19032 (C-0-D10901-V19032-cpt)abstDomain: V10251 (C-0-D10901-V10251-cpt)specDomain: V10263 (C-0-D10901-V10263-cpt)specDomain: V10248 (C-0-D10901-V10248-cpt)specDomain: V10286 (C-0-D10901-V10286-cpt)specDomain: V10298 (C-0-D10901-V10286-V10298-cpt)specDomain: V19584 (C-0-D10901-V10286-V19584-cpt)specDomain: V10302 (C-0-D10901-V10302-cpt)specDomain: V10259 (C-0-D10901-V10259-cpt)abstDomain: V19605 (C-0-D10901-V19605-cpt)abstDomain: V16764 (C-0-D10901-V16764-cpt)abstDomain: V19366 (C-0-D10901-V19366-cpt)abstDomain: V19080 (C-0-D10901-V19080-cpt)abstDomain: V19600 (C-0-D10901-V19600-cpt)abstDomain: V19601 (C-0-D10901-V19601-cpt)abstDomain: V19083 (C-0-D10901-V19083-cpt)abstDomain: V19606 (C-0-D10901-V19606-cpt)vocSet: D11555 (C-0-D11555-cpt)specDomain: V13940 (C-0-D11555-V13940-cpt)abstDomain: V19313 (C-0-D11555-V13940-V19313-cpt)abstDomain: V19316 (C-0-D11555-V13940-V19313-V19316-cpt)abstDomain: V10416 (C-0-D11555-V13940-V19313-V19316-V10416-cpt)specDomain: V14006 (C-0-D11555-V13940-V19313-V19316-V10416-V14006-cpt)specDomain: V11595 (C-0-D11555-V13940-V19313-V19316-V10416-V14006-V11595-cpt)specDomain: V12205 (C-0-D11555-V13940-V19313-V19316-V10416-V14006-V11595-V12205-cpt)specDomain: V11569 (C-0-D11555-V13940-V19313-V19316-V10416-V11569-cpt)specDomain: V19587 (C-0-D11555-V13940-V19313-V19316-V10416-V19587-cpt)abstDomain: V19105 (C-0-D11555-V13940-V19313-V19105-cpt)specDomain: V10418 (C-0-D11555-V13940-V19313-V19105-V10418-cpt)specDomain: V11580 (C-0-D11555-V13940-V19313-V19105-V11580-cpt)specDomain: V16927 (C-0-D11555-V13940-V19313-V19105-V16927-cpt)abstDomain: V10428 (C-0-D11555-V13940-V10428-cpt)specDomain: V10441 (C-0-D11555-V13940-V10428-V10441-cpt)abstDomain: V10429 (C-0-D11555-V13940-V10429-cpt)specDomain: V10430 (C-0-D11555-V13940-V10429-V10430-cpt)specDomain: V19089 (C-0-D11555-V13940-V10429-V10430-V19089-cpt)specDomain: V16815 (C-0-D11555-V13940-V10429-V16815-cpt)specDomain: V11591 (C-0-D11555-V13940-V10429-V11591-cpt)abstDomain: V19367 (C-0-D11555-V13940-V19367-cpt)abstDomain: V19368 (C-0-D11555-V13940-V19368-cpt)abstDomain: V16772 (C-0-D11555-V13940-V16772-cpt)abstDomain: V19382 (C-0-D11555-V13940-V19382-cpt)abstDomain: V14008 (C-0-D11555-V13940-V14008-cpt)abstDomain: V14013 (C-0-D11555-V13940-V14013-cpt)abstDomain: V16930 (C-0-D11555-V13940-V16930-cpt)specDomain: V16773 (C-0-D11555-V13940-V16930-V16773-cpt)abstDomain: V19395 (C-0-D11555-V13940-V19395-cpt)vocSet: D11603 (C-0-D11603-cpt)specDomain: V19615 (C-0-D11603-V19615-cpt)