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		The Temporal Reference Systems schema for GML 3.1 provides constructs for handling various styles of temporal reference system. 
    This schema reflects a partial implementation of the model described in ISO 19108:2002. 
    Copyright (c) 2002-2005 OGC, All Rights Reserved.
	For conditions, see OGC Software Notice http://www.opengeospatial.org/about/?page=ipr
	
	
	
	
	
	
	
	
		
			Abstract element serves primarily as the head of a substitution group for temporal reference systems.
		
	
	
	
		
			A value in the time domain is measured relative to a temporal reference system. Common 
        types of reference systems include calendars, ordinal temporal reference systems, and 
        temporal coordinate systems (time elapsed since some epoch, e.g. UNIX time).
		
		
			
				
					
				
			
		
	
	
	
	
	
	
	
		
			A temporal coordinate system is based on a continuous interval scale defined in terms of a single time interval.
		
		
			
				
					
						
						
					
					
				
			
		
	
	
	
	
	
	
	
		
			In an ordinal reference system the order of events in time can be well 
      established, but the magnitude of the intervals between them can not be 
      accurately determined (e.g. a stratigraphic sequence).
		
		
			
				
					
				
			
		
	
	
	
	
	
		
			Ordinal temporal reference systems are often hierarchically structured 
      such that an ordinal era at a given level of the hierarchy includes a 
      sequence of shorter, coterminous ordinal eras. This captured using the member/group properties.  
      
      Note that in this schema, TIme Ordinal Era is patterned on TimeEdge, which is a variation from ISO 19108.  
      This is in order to fulfill the requirements of ordinal reference systems based on eras delimited by 
      named points or nodes, which are common in geology, archeology, etc.  
      
      This change is subject of a change proposal to ISO
		
		
			
				
					
					
					
					
					
						
							An Era may be composed of several member Eras. The "member" element implements the association to the Era at the next level down the hierarchy.  "member" follows the standard GML property pattern whereby its (complex) value may be either described fully inline, or may be the target of a link carried on the member element and described fully elsewhere, either in the same document or from another service.
						
					
					
						
							In a particular Time System, an Era may be a member of a group.  The "group" element implements the back-pointer to the Era at the next level up in the hierarchy. 

If the hierarchy is represented by describing the nested components fully in the their nested position inside "member" elements, then the parent can be easily inferred, so the group property is unnecessary.  

However, if the hierarchy is represented by links carried on the "member" property elements, pointing to Eras described fully elsewhere, then it may be useful for a child (member) era to carry an explicit pointer back to its parent (group) Era.
						
					
				
			
		
	
	
	
		
			
		
		
	
	
	
	
	
	
	
		
			A calendar is a discrete temporal reference system 
      that provides a basis for defining temporal position to a resolution of one day. 
      A single calendar may reference more than one calendar era.
		
		
			
				
					
						
							Link to the CalendarEras that it uses as a reference for dating.
						
					
				
			
		
	
	
	
		
			
		
		
	
	
	
	
	
		
			In every calendar, years are numbered relative to the date of a 
      reference event that defines a calendar era. 
      In this implementation, we omit the back-pointer "datingSystem".
		
		
			
				
					
						
							Name or description of a mythical or historic event which fixes the position of the base scale of the calendar era.
						
					
					
						
							Date of the referenceEvent expressed as a date in the given calendar. 
              In most calendars, this date is the origin (i.e., the first day) of the scale, but this is not always true.
						
					
					
						
							Julian date that corresponds to the reference date.  
              The Julian day numbering system is a temporal coordinate system that has an 
              origin earlier than any known calendar, 
              at noon on 1 January 4713 BC in the Julian proleptic calendar.  
              The Julian day number is an integer value; 
              the Julian date is a decimal value that allows greater resolution. 
              Transforming calendar dates to and from Julian dates provides a 
              relatively simple basis for transforming dates from one calendar to another.
						
					
					
						
							Period for which the calendar era was used as a basis for dating.
						
					
				
			
		
	
	
	
		
			
		
		
	
	
	
	
	
	
	
		
			A clock provides a basis for defining temporal position within a day. 
      A clock must be used with a calendar in order to provide a complete description of a temporal position 
      within a specific day.
		
		
			
				
					
						
							Name or description of an event, such as solar noon or sunrise, 
              which fixes the position of the base scale of the clock.
						
					
					
						
							time of day associated with the reference event expressed as 
              a time of day in the given clock. The reference time is usually the origin of the clock scale.
						
					
					
						
							24 hour local or UTC time that corresponds to the reference time.
						
					
					
				
			
		
	
	
	
		
			
		
		
	
	




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