INTERNET-DRAFT Mari Korkea-aho
Internet Engineering Task Force Haitao Tang
Document: draft-korkea-aho-spatial-dataset-00.txt Nokia
Expires: May 2001 James M. Polk
Cisco
Kenji Takahashi
NTT
Nov. 2000
A Common Spatial Location Dataset
Status of This Memo
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Abstract
This work proposes a common format and extensible framework of
expressing location information in the Internet. The design aims at
bridging various existing/proposed data representation formats, as well
as meeting the requirements of existing/proposed location-aware
applications/services.
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Contents
1. Introduction 2
2. Existing Spatial Location Expressions 2
3. Location Information Required by Services 3
4. Common Location Data Set 4
4.1 Common Data Set 4
4.2 Syntax of the Elements 5
4.3 Encoding of the Data Set 7
5. Extendible Framework 8
6. Security Considerations 9
7. Acknowledgements 10
8. Author's Addresses 10
9. References 10
1. Introduction
Currently many organizations are working on location-related
technologies, and how to express and provide location information to
services and applications in the Internet. Such organizations are IETF,
OpenGIS, 3GPP, LIF, WAP Forum, W3C, etc.
Each of them basically specifies its own way of providing and expressing
location information to services and applications. This raises a serious
problem - the various location information formats, services, and
applications will not be interoperable in the Internet. Therefore, a
common extendible way of expressing and transferring location
information for services and applications in the Internet is needed.
This work thus proposes a common format and extensible framework of
expressing location information in the Internet. The design aims at
bridging various existing/proposed data representation formats, as well
as meeting the requirements of existing/proposed location-aware
services. Security is one of the key issues to be considered with the
progress of the work.
2. Existing Spatial Location Expressions
There are many existing or proposed location expressions from a number
of organizations (e.g. IETF, OpenGIS, 3GPP, LIF, WAP Forum, and W3C).
Some of them are listed below:
- Expression standardized for GSM and UMTS to be used internally in the
mobile networks (called here "3GPP") [1]
- An interface towards mobile networks in consideration by LIF [2]
- The Geography Markup Language by the OpenGIS Consortium (GML) [3]
- NaVigation Markup Language (NVML) [4] and Point Of Interest eXchange
Language (POIX) [5] submitted to the W3C
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- GeoTags for HTML resource discovery [6,7]
- National Marine Electronics Association (NMEA) interface and protocol
[8] often used by GPS receivers
- VCard and ICalendar [9, 10, 11] include elements to specify position
- A Means for Expressing Location Information in the Domain Name System
(DNS-LOC) [12]
- Proposed Simple Text Format for the Spatial Location Protocol (SLoP)
[13]
In brief most of the formats express location with latitude, longitude,
using WGS84 as reference datum. GML, LIF, NAVML, and POIX also enable
expressions using other coordinate systems and reference datum. Some
allow altitude, if the data is available. In the location expressions,
altitude usually means the height above WGS84 reference ellipsoid, while
it is unclear in some cases.
Most of the formats focus on the specification of the location of a
point object, whereas others include also the expression of object
shapes (3GPP, LIF, and GML). In DNS-LOC and NVML radial size of object
can be defined.
When the accuracy for estimating a location is defined, it is mostly
expressed as horizontal and vertical error. Though, the 3GPP proposal
includes more complex accuracy descriptions.
LIF, POIX, NMEA, and 3GPP include also fields for velocity/speed. It is
expressed as horizontal speed in all the cases except 3GPP. The 3GPP
proposal defines horizontal velocity (horizontal speed + bearing) and
vertical velocity (vertical speed + vertical direction).
Direction of movement is also included in LIF, POIX, and NMEA, using
true and/or magnetic North. POIX and NMEA include possibility to define
the course as well.
3. Location Information Required by Services
Many different types of location-aware services have been identified,
e.g. information services (e.g. yellow pages, point-of-interest
services), navigation & guidance, notifications (ads, traffic alerts,
weather services, etc.), information memorizing & association, tracking
& resource management, authorization, location specific resource
management and discovery, location sensitive billing, network
management.
It appears that most of the different services will primarily need
absolute spatial location information as input. This is also the format
that most existing location measurement systems can provide. Some of the
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services also need descriptive location such as addresses, regions, etc.
This kind of information is generally created by manual input or via
transformation services.
Altitude and accuracy information will bring added value to services,
but most of them can live without it. It is quite evident that in
addition to location information it is important to attach the time of
measurement to the location. This can be essential to the processing and
management of location information. Other information that could bring
added value to services include the orientation of the object, its
moving direction, intended course, and speed.
What about the size and shape of the object? This information could
principally be used in two ways; firstly to describe the object which is
positioned in order to determine what region it is covering (e.g. in
finding, guidance, notification, tracking, authorization, resource
discovery, billing and management services), secondly to indicate the
region of interest or object to attach information to (finding
information and information memorizing & association). Since most of the
objects for positioning are of minor size (<10 m), the size and shape of
an object usually do not have significance for the location of the
object. It is also difficult to express shapes and sizes in an
interoperable way. In fact, size and shape can be understood and
specified as attributes associated to a location rather than location
itself.
4. Common Location Data Set
4.1 Common Data Set
The proposal of a common data set is based on identified elements
important to applications, and on the available data from different
devices and interfaces.
Co-ordinates and Datum (mandatory)
When reviewing the various existing interfaces and data representation
formats, we find that most of them support coordinates expressed in
latitude, longitude, and altitude (optional) using WGS-84 datum. Thus we
propose to use these in the common data set, where latitude and
longitude would be mandatory. In order to keep the common data set
simple, no other datum or coordinate systems are supported. We have
chosen to enable the optional altitude to be expressed both as the WGS-
84 reference ellipsoid and mean sea level as reference.
Location Accuracy (optional)
Location accuracy is the estimation/measurement error of a location. The
different interfaces include different types of accuracy information. We
propose to include the most common way to express this, i.e. horizontal
accuracy, by circle of radius from the positioned point, and height
accuracy, by range from the positioned point.
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Time (mandatory)
Time is the time of a measurement/fix of a location of an object. It is
an important factor for location information. With the help of the time
it is easier to manage location information and it enables different
kinds of approximations. It is a mandatory element.
Speed (optional)
Speed is indicated as horizontal ground and vertical speed. This
expression is chosen because many systems are able to indicate
horizontal ground and vertical speed.
Direction (optional)
Direction indicates the direction of movement. It is expressed in a 2-
dimensional (horizontal) frame indicated by the magnetic (or true)
North.
Course (optional)
Course indicates the direction from the current position to a defined
destination. It is expressed in a 2-dimensional (horizontal) frame
indicated by the magnetic (or true) North.
Orientation (optional)
Orientation describes the orientation of the positioned object.
Orientation is often given with a local coordinate system as reference.
Since this reference frame can be different for different objects, it
will be difficult to make a common expression based on this. One
possibility would be to attach an object type indicating directly the
used reference framework. Instead of such a solution, we propose a
method where the orientation is expressed in a 2-dimensional
(horizontal) frame indicated by the magnetic (or true) North, and a
vertical element expressed by the angle between horizontal plane and the
main axis of the object.
Un-specified Attributes (optional)
An un-specified element is incorporated into the common set to include
some application specific elements. The attributes should be relevant
for location payload and not conflict with defined/existing attributes.
This field should be used with consideration.
4.2 Syntax of the Elements
Some of the existing data formats allow different optional ways to
express the data elements and include syntax information. However, in
order to keep processing as simple as possible we prefer only one single
way of expression. Here is the syntax of the elements in the common data
set:
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Element Expression format Example
Coordinates
-Latitude [N/S]degree.minute.second, N60.08.00.235556
(mandatory) range [0-90], decimal fraction
in arbitrary length
-Longitude [E/W]degree.minute.second, E25.00.00
(mandatory) range [0-180], decimal fraction
in arbitrary length
-Altitude above meter from WGS-84 reference +12
datum ellipsoid, + above, - below,
(optional) decimal fraction in arbitrary
length
-Altitude above in meter, + above, - below, +10
mean sea level decimal fraction in arbitrary
(optional) length
Location Accuracy
-Horizontal by circle of radius from the 50.0
accuracy positioned point in meter,
(optional) decimal fraction in arbitrary
length
-Altitude in meter, decimal fraction in 2.5
accuracy arbitrary length
(optional)
Time [14, 15] Real time of the measurement/fix
(mandatory) 1999-08-15T11:16:31.0 +2:00
YYYY-MM-DDThh:mm:ss.sTZD, where
YYYY = four-digit year
MM = two-digit month (01=January, etc.)
DD = two-digit day of month (01-31)
hh = two digits of hour (00-23)
mm = two digits of minute (00-59)
ss = two digits of second (00-59)
s = one or more digits representing a decimal
fraction of a second
TZD = time zone designator (Z or +hh:mm or -hh:mm)
Speed
- Ground speed x.f [m/s | km/h | mph | knot ], 2.0 m/s
(optional) where default meter/second or m/s,
f arbitrary decimal fractions
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- Vertical speed x.f [m/s | km/h | mph | knot ], 1.0 m/s
(optional) where f arbitrary decimal fractions
Direction magnetic/true direction,
(optional) 360 degrees from North clockwise
[M | T] x.f, degrees and fractional M240
degrees in arbitrary length, M default
Course magnetic/true direction, M30
(optional) 360 degrees from North clockwise
[M | T] x.f, degrees and fractional
degrees in arbitrary length, M default
Orientation
- Horizontal magnetic/true direction,
(optional) 360 degrees from North clockwise M240
[M | T] x.f, degrees and fractional
degrees in arbitrary length, M default
- Vertical (pitch) [+|-] [0-180].f degrees, fractional 0
(optional) degrees in arbitrary length
Un-specified attribute: value, [value] car_orientation:
Attributes 360,40,20
(optional)
4.3 Encoding of the Data Set
The data elements can be encoded in many different ways, e.g., text
based attribute-value pairs, binary, MIME, XML, etc. In order to enable
interoperability, again, we need a common way of encoding the
parameters. We propose XML. The advantages of XML are that the encoding
is easily understandable, human readable, and standard tools and parsers
can be used. In addition to this, many of the other proposals make use
of XML. A possible disadvantage of using XML is that it is quite
verbose.
The XML.dtd for the common expression is:
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An XML-encoded location example:
N60.08.00.235556 E025.00.00+12+1050.02.52.01.0M240M30M24003604020
5. Extendible Framework
A framework enables to express the same location in different ways, or
add extensions to a certain expression. That is, the location expression
can be gathered by combining different location information modules. We
propose an XML-based framework.
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Since we assume that the XML-parser performs validation, the framework
needs to include the references to the dtds of the data subsets of the
framework. We assume that the receiving party has the required dtds,
otherwise a URL pointing to the dtd should be available. One way of
creating the framework is to create a LOC_FRAME document that
incorporates the dtds of the different location representation modules.
Below is an example, where the framework incorporates two subsets, the
"slo_default" subset and "my_loc" subset:
%slo_default_dtd;
%my_loc_dtd;
]>
...
...
If each module is identified by an identifier (e.g. the system or public
identifier of the document, or the XML-root element), it will be easier
to identify the data set and to process and transform the data. In order
to avoid conflicts in the structure document, the different data sets
should include unique XML-elements. This could be achieved by using XML-
namespaces [16].
Another option to be further studied is to include the different dtds in
an external dtd (e.g. SLO_MY_LOC.dtd) and then reference the dtd in the
location representation document, in a similar manner as proposed in the
XHTML modularization [17]. If used in combination with namespaces this
approach would allow interleaving of elements from the different
location representation data sets.
6. Security Considerations
Location information is potentially private or sensitive even though
some parties (such as shops) like to release their location information
to the public. The authors believe that location information should be
delivered based on the policy set to the location information. In
addition, certain security mechanisms should be used to protect the
location information, if required (as most of the cases). This should be
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looked into more detail when defining the complete payload for
transferring the location data.
7. Acknowledgements
The authors would like to thank all those who have provided comments to
this document.
8. Author's Addresses
Mari Korkea-aho
Nokia Research Center
P.O. Box 407
FIN-00045 Nokia Group
Finland
Email: mari.korkea-aho@nokia.com
Haitao Tang
Nokia Research Center
P.O. BOX 407
FIN-00045 Nokia Group
Finland
Email: haitao.tang@nokia.com
James Polk
Cisco Systems
18581 N. Dallas Parkway
Dallas, Texas 75287
Phone: +1 972.813.5208
Email: jmpolk@cisco.com
Kenji Takahashi
Information Sharing Platform Laboratories
NTT
3-9-11 Midoricho
Musashino, Tokyo 180-8585 Japan
Phone: +81 422 59 6668
Email: kt@nttlabs.com
9. References
[1] 3rd Generation Partnership Project, Technical Specification
Group Core Network, Universal Geographical Area Description
(GAD), Release 1999, Technical Specification, 3G TS 23.032
V3.1.0 (2000-03)
[2] Definition of a Mobile Location Query API, Contribution to
Location Inter-operability Forum (LIF), API Specification, v.
0.5, 18 Oct 2000
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Internet Draft A Common Spatial Location Dataset Nov. 2000
[3] Lake, R., Cuthbert, A. (eds.), Geography Markup Language (GML)
v1.0, OGC Document Number: 00-029, 12-May-2000,
http://www.opengis.org/techno/specs/00-029.pdf
[4] Sekiguchi, et al., NaVigation Markup Language (NVML), W3C Note
6 Aug 1999,http://www.w3.org/TR/NVML
[5] Hiroyuki Kanemitsu, Tomihisa Kamada, POIX: Point Of Interest
eXchange Language Specification, W3C Note - 24 June 1999,
http://www.w3.org/TR/poix
[6] Daviel, A., Geographic registration of HTML documents, , April 2000,
http://geotags.com/geo/draft-daviel-html-geo-tag-03.txt
[7] Daviel, A., Geographic extensions for HTTP transactions,
, April 2000,
http://geotags.com/geo/draft-daviel-http-geo-header-02.txt
[8] Bennett P., The NMEA FAQ, version 6.3, April 25, 2000,
http://vancouver-webpages.com/pub/peter/nmeafaq.txt
[9] Internet Mail Consortium, "vCard - The Electronic Business Card
Version 2.1",
September 18, 1996, http://www.imc.org/pdi/vcard-21.txt
[10] Dawson, F., Howes, T. , vCard MIME Directory Profile, IETF RFC
2426, September 1998, http://www.imc.org/rfc2426
[11] Dawson, F., Stenerson, D., Internet Calendaring and Scheduling
Core Object Specification (iCalendar), RFC 2445, November 1998,
http://www.imc.org/rfc2445
[12] Davis, C., Vixie, P., Goodwin, T., Dickinson, I., A Means for
Expressing Location Information in the Domain Name System, IETF
RFC 1876, January 1996,
ftp://ftp.funet.fi/pub/doc/rfc/rfc1876.txt
[13] Mahy, R., A Simple Text Format for the Spatial Location
Protocol (SLoP), Internet draft, July 2000,
http://search.ietf.org/internet-drafts/draft-mahy-spatial-
simple-coord-00.txt
[14] Wolf, M., Wicksteed, C., W3C note, Date and Time Formats, 15
September 1997, http://www.w3.org/TR/1998/NOTE-datetime-
19980827
[15] Kuhn, M., A Summary of the International Standard Date and Time
Notation, http://www.cl.cam.ac.uk/~mgk25/iso-time.html
[16] Bray et al., Namespaces in XML, World Wide Web Consortium 14
January 1999, http://www.w3.org/TR/1999/REC-xml-names-19990114
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Internet Draft A Common Spatial Location Dataset Nov. 2000
[17] Adams, et al., Modularization of XHTML, 20 October 2000,
http://www.w3.org/TR/2000/CR-xhtml-modularization-20001020/
xhtml-modularization-20001020.html
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