OGC WKT Coordinate System Issues

This document is intended to discuss some issues that arrise in attempting to use OpenGIS Well Known Text descriptions of coordinate systems. It discusses various vendor implementations and issues between the original "Simple Features" specification (ie. SF-SQL 99-049) and the newer Coordinate Transformation Services (CT) specification (01-009) which defines an extended form of WKT.

WKT Implementations

At this time I am aware of at least the following software packages that use some form of WKT internally, or for interchange of coordinate system descriptions:

Projection Parameters

The various specs do not list a set of projections, and the parameters associated with them. This leads to various selection of parameter names (and sometimes projection names) from different vendors. I have attempted to maintain a list of WKT bindings for different projections as part of my
GeoTIFF Projections List registry. Please try to adhere to the projection names and parameters listed there. That list also tries to relate the projections to the GeoTIFF, EPSG and PROJ.4 formulations where possible.

The one case where it isn't followed by a vendor that I am aware of ESRIs definition of Lambert Conformal Conic. In EPSG there is a 1SP and a 2SP form of this. ESRI merges them, and just have different parameters depending on the type.

One other issue is that the CT specification does explicitly list parameters for the Transverse Mercator, LCC 1SP and LCC 2SP projections; however, it lists standard_parallel1 and standard_parallel2 as parameters for LCC 2SP which conflicts with the existing usage of standard_parallel_1 and standard_parallel_2 and conflicts with examples in the same CT spec. My position is that the table in section 10.x of the CT spec is in error and that the widely used form is correct. Note that the table in the CT spec conflicts with other examples in the same spec.

A third issue is the formulation for Albers. While I have used longitude_of_center and latitude_of_center ESRI uses Central_meridian and latitude_of_origin.

ESRI:

PROJECTION["Albers"],
PARAMETER["False_Easting",1000000.0],
PARAMETER["False_Northing",0.0],
PARAMETER["Central_Meridian",-126.0],
PARAMETER["Standard_Parallel_1",50.0],
PARAMETER["Standard_Parallel_2",58.5],
PARAMETER["Latitude_Of_Origin",45.0],
OGR:

PROJECTION["Albers"],
PARAMETER["standard_parallel_1",50],
PARAMETER["standard_parallel_2",58.5],
PARAMETER["longitude_of_center",-126],
PARAMETER["latitude_of_center",45],
PARAMETER["false_easting",1000000],
PARAMETER["false_northing",0],

Datum Names

In Simple Features style WKT, the name associated with a datum is the only way to identify the datum. In CT WKT the datum can also have a TOWGS84 parameter indicating its relationship to WGS84, and an AUTHORITY parameter relating it to EPSG or some other authority space. However, in SF WKT the name itself is the only key.

By convention OGR and Cadcorp have translated the datum names in a particular way from the EPSG database in order to produce comparible names. The rule is to convert all non alphanumeric characters to underscores, then to strip any leading, trailing or repeating underscores. This produces well behaved datum names like "Nouvelle_Triangulation_Francaise".

However, other vendors have done different things. ESRI seems to follow a similar convention but prefixes all datum names with "D_" as well, giving names like "D_WGS_1972". Also they have lots of other differences for reasons that are not clear. For instance for what Cadcorp and OGR call "Nouvelle_Triangulation_Francaise", they call it "D_NTF". Oracle appears to use the raw names without cleanup. So for NTF they use "NTF (Paris meridian)".

The short result of this is that it is almost impossible to recognise and compare datums between different Simple Features implementations, though I have had some success in translating ESRI datum names to match Cadcorp/OGR conventions, with some special casing.

Parameter Ordering

It is worthwhile keeping in mind that the BNF grammars for WKT in the SF specs, and the CT spec imply specific orders for most items. For instance the BNF for the PROJCS item in the CT spec is
<projected cs> = 
  PROJCS["<name>", <geographic cs>, <projection>, {<parameter>,}* <linear unit> {,<twin axes>}{,<authority>}]
This clearly states that the PROJECTION keyword follows the GEOGCS, followed by the UNIT, AXIS and AUTHORITY items. Providing them out of order is technially a violation of the spec. On the other hand, WKT consumers are encouraged to be flexible on ordering.

Units of PARAMETERs

The linear PARAMETER values in a PROJCS must be in terms of the linear units for that PROJCS. I think the only linear units are the false easting and northing type values. Thus, in common cases like a state plane zone in feet, the false easting and northing will also be in feet.

The angular PARAMETER values in a PROJCS must be in terms of the angular units of the GEOGCS. If the GEOGCS is in gradians, for instance, then all the projection angles must also be in gradians!

Units of PRIMEM

What units should the prime meridian appear in?

Sign of TOWGS84 Rotations

Discussion

In EPSG there are two methods of defining the 7 parameter bursa wolf parameters, 9606 (position vector 7-parameter) and 9607 (coordinate frame rotation). The only difference is that the sign of the rotation coefficients is reversed between them.

I (Frank Warmerdam) had somehow convinced myself that the TOWGS84 values in WKT were supposed to be done using the sense in 9606 (position vector 7-parameter) and that if I read a 9607 I would need to switch the rotation signs before putting it into a TOWGS84 chunk in WKT.

However, I see in the WKT dump you (Martin from Cadcorp) sent me you are using the 9607 sense. For instance, this item appears to use 9607 values directly without switching the sign.

 GEOGCS["DHDN",
    DATUM["Deutsche_Hauptdreiecksnetz",
      SPHEROID["Bessel 1841",6377397.155,299.1528128,AUTHORITY["EPSG","7004"]],
      TOWGS84[582,105,414,-1.04,-0.35,3.08,8.3],
      AUTHORITY["EPSG","6314"]],
    PRIMEM["Greenwich",0,AUTHORITY["EPSG","8901"]],
    UNIT["DMSH",0.0174532925199433,AUTHORITY["EPSG","9108"]],
    AXIS["Lat",NORTH],AXIS["Long",EAST],AUTHORITY["EPSG","4314"]]
I read over the TOWGS84[] clause in the 1.0 CT spec, and it just talks about them being the Bursa Wolf transformation parameters (on page 22, 7.3.18). I also scanned through to 12.3.15.2 and 12.3.27 and they are nonspecific as to the handedness of the TOWGS84 rotations.

I am seeking a clarification of whether TOWGS84 matches EPSG 9606 or EPSG 9607. Furthermore, I would like to see any future rev of the spec clarify this, referencing the EPSG method definitions.

Martin wrote back that he was uncertain on the correct signage and that the Adam had programmed the Cadcorp implementation imperically, according to what seemed to work for the test data available.

I am prepared to adhere to the Cadorp sign usage (as per EPSG 9607) if this can be clarified in the specification.

Current state of OGR implementation

OGR imports from/exports to WKT assumes EPSG 9606 convention (position vector 7-parameter), as proj.4 does.

When importing from EPSG parameters expressed with EPSG 9607, it does the appropriate conversion (negating the sign of the rotation terms).

Longitudes Relative to PRIMEM?

Another related question is whether longtiudinal projection parameters (ie. central meridian) are relative to the GEOGCS prime meridian or relative to greenwich. While the simplest approach is to treat all longitudes as relative to Greenwich, I somehow convinced myself at one point that the longitudes were intended to be relative to the prime meridian. However, a review of 7.3.11 (describing PARAMETER) in the CT 1.0 spec provides no support for this opinion, and an inspection of EPSG 25700 in Cadcorp also suggests that the central meridian is relative to greenwich, not the prime meridian.

PROJCS["Makassar (Jakarta) / NEIEZ",
    GEOGCS["Makassar (Jakarta)",
        DATUM["Makassar",
            SPHEROID["Bessel 1841",6377397.155,299.1528128,
                AUTHORITY["EPSG","7004"]],
            TOWGS84[0,0,0,0,0,0,0],
            AUTHORITY["EPSG","6257"]],
        PRIMEM["Jakarta",106.807719444444,
            AUTHORITY["EPSG","8908"]],
        UNIT["DMSH",0.0174532925199433,
            AUTHORITY["EPSG","9108"]],
        AXIS["Lat","NORTH"],
        AXIS["Long","EAST"],
        AUTHORITY["EPSG","4804"]],
    PROJECTION["Mercator_1SP",
        AUTHORITY["EPSG","9804"]],
    PARAMETER["latitude_of_origin",0],
    PARAMETER["central_meridian",110],
    PARAMETER["scale_factor",0.997],
    PARAMETER["false_easting",3900000],
    PARAMETER["false_northing",900000],
    UNIT["metre",1,
        AUTHORITY["EPSG","9001"]],
    AXIS["X","EAST"],
    AXIS["Y","NORTH"],
    AUTHORITY["EPSG","25700"]]
Based on this, I am proceeding on the assumption that while parameters are in the units of the GEOGCS they are not relative the GEOGCS prime meridian.

Numerical Precision in WKT

The specification does not address the precision to which values in WKT should be stored. Some implementations, such as Oracles apparently, use rather limited precision for parameters such as Scale Factor making it difficult to compare coordinate system descriptions or even to get comparible numerical results.

The best practice is to preserve the original precision as specified in the source database, such as EPSG where possible. Given that many systems do not track precision, at least it is advisable to produce values with the equivalent of the C "%.16g" format, maintaining 16 digits of precision, capturing most of the precision of a double precision IEEE floating point value.

Other Notes

  1. ESRI seems to use Equidistant_Cylindrical for what I know as Equirectangular.

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