## Hot answers tagged gis

5

library(tigris)
library(sp)
library(ggplot2)
library(ggthemes)
The tigris pkg is a better interface to TIGER data. devtools::install_github("walkerke/tigris").
alabama <- primary_secondary_roads("alabama")
georgia <- primary_secondary_roads("georgia")
Base plots can combine both together without doing rbinding:
plot(alabama)
plot(georgia, ...

3

It seemed like your question was specifically about combining the shapefiles, so let me try to answer that.
In order for spRbind(...) to succeed several conditions must be met:
None of the line ID's can be duplicated. This is a problem because both shapefiles start their numbering at ID="0".
Both attribute tables must have exactly the same columns/column ...

3

I only have only limited knowledge of Boost.Geometry, but it seems it does not offer a straightforward solution to
your problem.
However, converting from cartesian to latitude, longtitude and height (i.e.
ellipsoidal coordinates) is a pretty simple algorithm. You can
find the implementation in navipedia.
If you can read FORTRAN, a more efficient ...

3

The method Polygon.getBoundary() computes the boundaries of the polygon. If the polygon has not holes (also only one boundary), a object of type LinearRing is returned.
If the polygons has holes - also more than one boundary - a object of type MultiLineString is returned.
Use the methode Polygon.getNumInteriorRing() to check if the polygon has holes and ...

2

1) Your query is correct but you coordinates are inverted. The correct coordinates order in the WKT format is POINT(x y), also POINT(longitude latitude)
This query give you the expected result:
SELECT ST_AsText(ST_Transform(ST_GeomFromText('POINT(-5.86424016952515 36.5277099609375)',4326),32630)) As check;
2) To get the UTM zone from a lat/long geometry ...

1

For 100 - 1000m spherical problems, it is easy to just convert to
cartesian space, using a equirectangular projection.
Then it continues with school mathematics:
Use the function "distance from line segment" which is easy to find ready implemented.
This fucntion uses (and sometimes returns) a relative forward/backward position for the projected point X on ...

1

I believe you need to create a custom fuzzy attribute for point instances. Can you try this? Right now I don't have the setup to run it all through.
import random
from factory.fuzzy import BaseFuzzyAttribute
class FuzzyPoint(BaseFuzzyAttribute):
def fuzz(self):
return Point(random.uniform(-180.0, 180.0),
...

1

You probably want to look at NMEA data since this is a common standard. You can generate your own information to test with and then you will actually know what to expect as data. Some example strings can be found at:
http://www.gpsinformation.org/dale/nmea.htm#stream
I think the GPGSV data is raw(ish) satellite information. Of course most GPS data has ...

1

GeodesicString uses geodesic interpolation -- that is, interpolation over the surface of the planet. If you had a geodesic segment from the north pole to the equator, the result would be an arc following the surface; if you had a linear segment, the result would be a line tunneling underground.

1

The methodology would be to detect a zoom change and apply a updated view with the new projection to the map.
First you have to detect the change of the resolution:
map.getView().on('change:resolution', changeProjection);
Secondly you look if you have reached the desired zoom level and then apply the projection:
var changeProjection = function() {
var ...

1

Firs thing is that following documentation of OpenGIS WKT Point(x,y) yours POINT(36.5277099609375 -5.86424016952515) is south of equator so you have to use 29S(EPSG:32729) and 30S(EPSG:32730)

1

Following the advice of package maintainer @chkaiser, I've sought out and finally discovered a way to do this within R. This blog post was a tremendous help and the getcartr package is fantastic.
First, get the Rcartogram and getcartr packages from GitHub:
library(devtools)
install_github("omegahat/Rcartogram")
install_github('chrisbrunsdon/getcartr', ...

1

ST_Intersection will give you a collection of pieces of the lines that are mutual, if you want a bit more tolerance use ST_Buffer on one of the lines first. Then do a Sum() of the ST_Length of those pieces.

1

Instead of using the cascaded_union method, it might be easier to write your own method to check if any two polygons intersect. If I'm understanding what you want to do correctly, you want to find if two polygons overlap, and then delete one of them and edit another accordingly.
You could so something like this (not the best solution, I'll explain why):
...

1

Without the full code it's kind of hard to answer but my first guess is that you didn't load the routing plugin's assets or not in the proper order (first the Leaflet script then the routing plugin, the other way around doesn't work):
<link rel="stylesheet" href="http://cdn.leafletjs.com/leaflet-0.7.3/leaflet.css" />
<link rel="stylesheet" ...

1

When in doubt you can always read the documentation, for example JTSFactoryFinder returns a com.vividsolutions.jts.geom.GeometryFactory, once you know that the other pieces fall into place as:
import com.vividsolutions.jts.geom.Coordinate;
import com.vividsolutions.jts.geom.GeometryFactory;
import com.vividsolutions.jts.geom.Point;
Meanwhile your ...

1

Prompted by Edzer Pebesma, a closer read of the sp::aggregate documentation indicates that FUN is applied to each attribute of x. So, instead of creating a long table with a factor column, creating two separate columns (one for each factor) seems to work.
wards2 <- readOGR(dsn = "wards", layer = "VOTING_SUBDIVISION_2010_WGS84") %>%
...

1

Build a planar straight-line graph (PSLG) of the polygon segments (linearithmic in the number of output elements), convert the polygons to PSLG cycles, determine the faces enclosed by those cycles (depth-first search, basically), and then the rest is sort of trivial. The hard part here is computing the PSLG, but there are libraries for that.

1

Not a complete answer, but I think you need to play with guides.
ggplot(legendGoal,
aes(Var1,Var2,
col=as.factor(value),
fill=as.factor(value))) +
geom_tile() +
guides(col = guide_legend(nrow = 3))

1

Most definitely not write your own. As you get more familiar with geographic data you will realize that this particular calculation isn't at all simple see for example this question for a detailed discussion. However most of the solutions (answers) given in that question only produce approximate results. Partly due to the fact that the earth is not a perfect ...

1

#test desired legend appearance
library(ggplot2)
library(reshape2)
#use color scheme shown here http://www.joshuastevens.net/cartography/make-a-bivariate-choropleth-map/
bvColors=c("#be64ac","#8c62aa","#3b4994","#dfb0d6","#a5add3","#5698b9","#e8e8e8","#ace4e4","#5ac8c8")
melt(matrix(1:9,nrow=3))
legendGoal=melt(matrix(1:9,nrow=3))
test<-ggplot(legendGoal, ...

1

First: serious kudos for a perfectly reproducible example for a semi-complex problem.
This isn't much more work:
# need this to ensure ggplot treats it as factor and so we can tell it
# not to drop the factor levels for the fill aesthetic
us_shps_frt$id <- factor(us_shps_frt$id)
# now we build a plot list
lapply(unique(us_shps_frt$id), function(x) {
...

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