Develop Reference

A large amount of points to create separate polygons (ArcGIS/QGIS)

Visual example of the data
I used a drone to create a DOF of a small area. During the flight, it takes a photo every 20sh seconds (40sh meters of a flight). I have created a CSV file, which I transferred to a point shapefile. In total, I made with drone 10 so-called "missions", each with 100-200 points which are "shaped" as squares on the map. What I want now is to create a polygon shapefile from the point shapefile.
Because those points sometimes overlap, I cannot use the "Aggregate Points" task, as it's only distance-based. I want to make polygons automatically, using some kind of script. What could help is the fact that a maximum time between two points (AKA photos taken) is 10-20 seconds, so if the time distance is over 3 minutes, it's another "mission". Can you help with such a script, that would quickly and automatically create as many polygons as there are missions?

Okay, I think I understand what you are trying to accomplish. Since no one replied I am going to give it a quick shot, so you have something to try.
I think the best strategy would be to:
Clustering algorithm: Try running a Clustering algorithm such as DBSCAN around the timestamp dimension to classify them based on time groups, instead of the distance (since, as you said, distance based separation is not enough to properly identify and separate the points). After which, you should have all the points classified between different groups with a column group id. Maximum distance parameter in the algorithm should be around 20 seconds steps, or even a minute (since you said each mission was separated at least about 3 minutes apart).
Feature based Polygon to point: At that point, then you run your generic Polygon_from_points(...) function that transforms these clustered points to polygons shapes based on a specific discriminant feature (which in your case is going to be each group id).
How does this work?: This would properly separate the groups first (time-based) and then you should be able to find a generic point to polygon based on a feature (Arcgis should have some).
I dont have an example dataset, nor any code written, but based on what you described I think it would work, hope it helps.

Compare two timeseries, how to find mapping positions?

Let's assume two similar timeseries like below. Both are similar and never equal. E.g. the length can be different and similar parts can be between non-similar parts. I've tried to indicate the similarity by black arrows.
I'm not a mathematician and so I'm questioning if is there an approximately (or perfect) fast way to find a mapping table between them? I've digged into dynamic time warping but at this point I'm thinking that dtw is not what I'm looking for (not sure).
The mapping table good be like
Sequence Location_Timeseries_0 Location_Timeseries_1 Length
0 LTO_0 LT1_0 N
1 LTO_1 LT1_1 M
...
Can someone put me into the right direction?

Based on what you say/show, DTW is perfect
See the bottom right of http://www.cs.ucr.edu/~eamonn/sampleslides2.jpg
or the right of http://www.cs.ucr.edu/~eamonn/sampleslides3.jpg

Colocalization in R / Cross-Correlation of 3D matrices

I hope this has not been asked before, but I am currently in the process of analyzing some microscopy pictures in R and I am not quite sure how to tackle this.
The situation is as follows:
- I have several pictures of different targets in cells which show spots of signal
- Some pictures show the same cells, but were aquired after others and are therefore a little "off" in x-, y- and z-direction
- Some, but by no means all of the pictures show colocalization = spots from one picture also show up on other pictures
Coming from the spot detection software, I now have data frames for all spots in each picture (one df per picture) with the x-, y- and z-coordinates.
I am now looking for
a) a way to align these matrices of spots from the different colors and thought that cross-correlation of the matrices might be a way to go (however, is there CC in 3D in R?)
b) a way to calculate the colocalization. As these are pictures and intrinsically noisy, even colocalized spots might have a little different coordinates. Is there a function of package in R which merges these data based on a threshold or other parameter of my choice?
Thanks a lot in advance for all your answers!!
Simon

Adding plotstick-like arrows to a scatterplot

This is my first post here, thought i have read a lot of your Q&A these last 6 months. I'm currently working on ADCP (Aquatic Doppler Current Profiler) data, handled by the "oce" package from Dan Kelley (a little bit of advertising for those who want to deal with oceanographic datas in R). I'm not very experienced in R, and i have read the question relative to abline for levelplot functions "How to add lines to a levelplot made using lattice (abline somehow not working)?".
What i currently have is a levelplot representing a time series of echo intensity (from backscattered signal, which is monitored in the same time as current is) data taken in 10m of depth, this 10m depth line is parted into 25 rows, where each measurement is done along the line. (see the code part to obtain an image of what i have)
(unfortunately, my reputation doesn't allow me to post images).
I then proceed to generate an other plot, which represents arrows of the current direction as:
The length of each arrow gives an indication of the current strength
Its orientation is represented (all of this is done by taking the two components of the current intensity (East-West / North-South) and represent the resulting current).
There is an arrow drawn for each tick of time (thus for the 1000 columns of my example data, there are always two components of the current intensity).
Those arrows are drawn at the beginning of each measurement cell, thus at each row of my data, allowing to have a representation of currents for the whole water column.
You can see the code part to have a "as i have" representation of currents
The purpose of this question is to understand how i can superimpose those two representations, drawing my current arrows at each row of the represented data, thus making a representation of both current direction, intensity and echo intensity.
Here i can't find any link to describe what i mean, but this is something i have already seen.
I tried with the panel function which seems to be the best option, but my knowledge of R and the handeling of this kind of work is small, and i hope one of you may have the time and the knowledges to help me to solve this problem way faster than i could.
I am, of course, available to answer any questions or give precisions. I may ask a lot more, after working on a large code for 6 months, my thirst for learning is now large.
Code to represent data :
Here are some data to represent what I have:
U (north/south component of velocity) and V (East/west):
U1= c(0.043,0.042,0.043,0.026,0.066,-0.017,-0.014,-0.019,0.024,-0.007,0.000,-0.048,-0.057,-0.101,-0.063,-0.114,-0.132,-0.103,-0.080,-0.098,-0.123,-0.087,-0.071,-0.050,-0.095,-0.047,-0.031,-0.028,-0.015,0.014,-0.019,0.048,0.026,0.039,0.084,0.036,0.071,0.055,0.019,0.059,0.038,0.040,0.013,0.044,0.078,0.040,0.098,0.015,-0.009,0.013,0.038,0.013,0.039,-0.008,0.024,-0.004,0.046,-0.004,-0.079,-0.032,-0.023,-0.015,-0.001,-0.028,-0.030,-0.054,-0.071,-0.046,-0.029,0.012,0.016,0.049,-0.020,0.012,0.016,-0.021,0.017,0.013,-0.008,0.057,0.028,0.056,0.114,0.073,0.078,0.133,0.056,0.057,0.096,0.061,0.096,0.081,0.100,0.092,0.057,0.028,0.055,0.025,0.082,0.087,0.070,-0.010,0.024,-0.025,0.018,0.016,0.007,0.020,-0.031,-0.045,-0.009,-0.060,-0.074,-0.072,-0.082,-0.100,-0.047,-0.089,-0.074,-0.070,-0.070,-0.070,-0.075,-0.070,-0.055,-0.078,-0.039,-0.050,-0.049,0.024,-0.026,-0.021,0.008,-0.026,-0.018,0.002,-0.009,-0.025,0.029,-0.040,-0.006,0.055,0.018,-0.035,-0.011,-0.026,-0.014,-0.006,-0.021,-0.031,-0.030,-0.056,-0.034,-0.026,-0.041,-0.107,-0.069,-0.082,-0.091,-0.096,-0.043,-0.038,-0.056,-0.068,-0.064,-0.042,-0.064,-0.058,0.016,-0.041,0.018,-0.008,0.058,0.006,0.007,0.060,0.011,0.050,-0.028,0.023,0.015,0.083,0.106,0.057,0.096,0.055,0.119,0.145,0.078,0.090,0.110,0.087,0.098,0.092,0.050,0.068,0.042,0.059,0.030,-0.005,-0.005,-0.013,-0.013,-0.016,0.008,-0.045,-0.021,-0.036,0.020,-0.018,-0.032,-0.038,0.021,-0.077,0.003,-0.010,-0.001,-0.024,-0.020,-0.022,-0.029,-0.053,-0.022,-0.007,-0.073,0.013,0.018,0.002,-0.038,0.024,0.025,0.033,0.008,0.016,-0.018,0.023,-0.001,-0.010,0.006,0.053,0.004,0.001,-0.003,0.009,0.019,0.024,0.031,0.024,0.009,-0.009,-0.035,-0.030,-0.031,-0.094,-0.006,-0.052,-0.061,-0.104,-0.098,-0.054,-0.161,-0.110,-0.078,-0.178,-0.052,-0.073,-0.051,-0.065,-0.029,-0.012,-0.053,-0.070,-0.040,-0.056,-0.004,-0.032,-0.065,-0.005,0.036,0.023,0.043,0.078,0.039,0.019,0.061,0.025,0.036,0.036,0.062,0.048,0.073,0.037,0.025,0.000,-0.007,-0.014,-0.050,-0.014,0.007,-0.035,-0.115,-0.039,-0.113,-0.102,-0.109,-0.158,-0.158,-0.133,-0.110,-0.170,-0.124,-0.115,-0.134,-0.097,-0.106,-0.155,-0.168,-0.038,-0.040,-0.074,-0.011,-0.040,-0.003,-0.019,-0.022,-0.006,-0.049,-0.048,-0.039,-0.011,-0.036,-0.001,-0.018,-0.037,-0.001,0.033,0.061,0.054,0.005,0.040,0.045,0.062,0.016,-0.007,-0.005,0.009,0.044,0.029,-0.016,-0.028,-0.021,-0.036,-0.072,-0.138,-0.060,-0.109,-0.064,-0.142,-0.081,-0.032,-0.077,-0.058,-0.035,-0.039,-0.013,0.007,0.007,-0.052,0.024,0.018,0.067,0.015,-0.002,-0.004,0.038,-0.010,0.056)
V1=c(-0.083,-0.089,-0.042,-0.071,-0.043,-0.026,0.025,0.059,-0.019,0.107,0.049,0.089,0.094,0.090,0.120,0.169,0.173,0.159,0.141,0.157,0.115,0.128,0.154,0.083,0.038,0.081,0.129,0.120,0.112,0.074,0.022,-0.022,-0.028,-0.048,-0.027,-0.056,-0.027,-0.107,-0.020,-0.063,-0.069,-0.019,-0.055,-0.071,-0.027,-0.034,-0.018,-0.089,-0.068,-0.129,-0.034,-0.002,0.011,-0.009,-0.038,-0.013,-0.006,0.027,0.037,0.022,0.087,0.080,0.119,0.085,0.076,0.072,0.029,0.103,0.019,0.020,0.052,0.024,-0.051,-0.024,-0.008,0.011,-0.019,0.023,-0.011,-0.033,-0.101,-0.157,-0.094,-0.099,-0.106,-0.103,-0.139,-0.093,-0.098,-0.083,-0.118,-0.142,-0.155,-0.095,-0.122,-0.072,-0.034,-0.047,-0.036,0.014,0.035,-0.034,-0.012,0.054,0.030,0.060,0.091,0.013,0.049,0.083,0.070,0.127,0.048,0.118,0.123,0.099,0.097,0.074,0.125,0.051,0.107,0.069,0.040,0.102,0.100,0.119,0.087,0.077,0.044,0.091,0.020,0.010,-0.028,0.026,-0.018,-0.020,0.010,0.034,0.005,0.010,0.028,-0.043,0.025,-0.069,-0.003,0.004,-0.001,0.024,0.032,0.076,0.033,0.071,0.000,0.052,0.034,0.058,0.002,0.070,0.025,0.056,0.051,0.080,0.051,0.101,0.009,0.052,0.079,0.035,0.051,0.049,0.064,0.004,0.011,0.005,0.031,-0.021,-0.024,-0.048,-0.011,-0.072,-0.034,-0.020,-0.052,-0.069,-0.088,-0.093,-0.084,-0.143,-0.103,-0.110,-0.124,-0.175,-0.083,-0.117,-0.090,-0.090,-0.040,-0.068,-0.082,-0.082,-0.061,-0.013,-0.029,-0.032,-0.046,-0.031,-0.048,-0.028,-0.034,-0.012,0.006,-0.062,-0.043,0.010,0.036,0.050,0.030,0.084,0.027,0.074,0.082,0.087,0.079,0.031,0.003,0.001,0.038,0.002,-0.038,0.003,0.023,-0.011,0.013,0.003,-0.046,-0.021,-0.050,-0.063,-0.068,-0.085,-0.051,-0.052,-0.065,0.014,-0.016,-0.082,-0.026,-0.032,0.019,-0.026,0.036,-0.005,0.092,0.070,0.045,0.074,0.091,0.122,-0.007,0.094,0.064,0.087,0.063,0.083,0.109,0.062,0.096,0.036,-0.019,0.075,0.052,0.025,0.031,0.078,0.044,-0.018,-0.040,-0.039,-0.140,-0.037,-0.095,-0.056,-0.044,-0.039,-0.086,-0.062,-0.085,-0.023,-0.103,-0.035,-0.067,-0.096,-0.097,-0.060,0.003,-0.051,0.014,-0.002,0.054,0.045,0.073,0.080,0.096,0.104,0.126,0.144,0.136,0.132,0.160,0.155,0.136,0.080,0.144,0.087,0.093,0.103,0.151,0.165,0.146,0.159,0.156,0.002,0.023,-0.019,0.078,0.031,0.038,0.019,0.094,0.018,0.028,0.064,-0.052,-0.034,0.000,-0.074,-0.076,-0.028,-0.048,-0.025,-0.095,-0.098,-0.045,-0.016,-0.030,-0.036,-0.012,0.023,0.038,0.042,0.039,0.073,0.066,0.027,0.016,0.093,0.129,0.138,0.121,0.077,0.046,0.067,0.068,0.023,0.062,0.038,-0.007,0.055,0.006,-0.015,0.008,0.064,0.012,0.004,-0.055,0.018,0.042)
U2=c(0.022,0.005,-0.022,0.025,-0.014,-0.020,-0.001,-0.021,-0.008,-0.006,-0.056,0.050,-0.068,0.018,-0.106,-0.053,-0.084,-0.082,-0.061,-0.041,-0.057,-0.123,-0.060,-0.029,-0.084,-0.004,0.030,-0.021,-0.036,-0.016,0.006,0.088,0.088,0.079,0.063,0.097,0.020,-0.048,0.046,0.057,0.065,0.042,0.022,0.016,0.041,0.109,0.024,-0.010,-0.084,-0.002,0.004,-0.033,-0.025,-0.020,-0.061,-0.060,-0.043,-0.027,-0.054,-0.054,-0.040,-0.077,-0.043,-0.014,0.030,-0.051,0.001,-0.029,0.008,-0.023,0.015,0.002,-0.001,0.029,0.048,0.081,-0.022,0.040,0.018,0.131,0.059,0.055,0.043,0.027,0.091,0.104,0.101,0.084,0.048,0.057,0.044,0.083,0.063,0.083,0.079,0.042,-0.021,0.017,0.005,0.001,-0.033,0.010,-0.028,-0.035,-0.012,-0.034,-0.055,-0.009,0.001,-0.084,-0.047,-0.020,-0.046,-0.042,-0.058,-0.071,0.013,-0.045,-0.070,0.000,-0.067,-0.090,0.012,-0.013,-0.013,-0.009,-0.063,-0.047,-0.030,0.046,0.026,0.019,0.007,-0.056,-0.062,0.009,-0.019,-0.005,0.003,0.022,-0.006,-0.019,0.020,0.025,0.040,-0.032,0.015,0.019,-0.014,-0.031,-0.047,0.010,-0.058,-0.079,-0.052,-0.044,0.012,-0.039,-0.007,-0.068,-0.095,-0.053,-0.066,-0.056,-0.033,-0.006,0.001,0.010,0.004,0.011,0.013,0.029,-0.011,0.007,0.023,0.087,0.054,0.040,0.013,-0.006,0.076,0.086,0.103,0.121,0.070,0.074,0.067,0.045,0.088,0.041,0.075,0.039,0.043,0.016,0.065,0.056,0.047,-0.002,-0.001,-0.009,-0.029,0.018,0.041,0.002,-0.022,0.003,0.008,0.031,0.003,-0.031,-0.015,0.014,-0.057,-0.043,-0.045,-0.067,-0.040,-0.013,-0.111,-0.067,-0.055,-0.004,-0.070,-0.019,0.009,0.009,0.032,-0.021,0.023,0.123,-0.032,0.040,0.012,0.042,0.038,0.037,-0.007,0.003,0.011,0.090,0.039,0.083,0.023,0.056,0.030,0.042,0.030,-0.046,-0.034,-0.021,-0.076,-0.017,-0.071,-0.053,-0.014,-0.060,-0.038,-0.076,-0.011,-0.005,-0.051,-0.043,-0.032,-0.014,-0.038,-0.081,-0.021,-0.035,0.014,-0.001,0.001,0.003,-0.029,-0.031,0.000,0.048,-0.036,0.034,0.054,0.001,0.046,0.006,0.039,0.015,0.012,0.034,0.022,0.015,0.033,0.037,0.012,0.057,0.001,-0.014,0.012,-0.007,-0.022,-0.002,-0.008,0.043,-0.041,-0.057,-0.006,-0.079,-0.070,-0.038,-0.040,-0.073,-0.045,-0.101,-0.092,-0.046,-0.047,-0.023,-0.028,-0.019,-0.086,-0.047,-0.038,-0.068,-0.017,0.037,-0.010,-0.016,0.010,-0.005,-0.031,0.004,-0.034,0.005,0.006,-0.015,0.017,-0.043,-0.007,-0.009,0.013,0.026,-0.036,0.011,0.047,-0.025,-0.023,0.043,-0.020,-0.003,-0.043,0.000,-0.018,-0.075,-0.045,-0.063,-0.043,-0.055,0.007,-0.063,-0.085,-0.031,0.005,-0.067,-0.059,-0.059,-0.029,-0.014,-0.040,-0.072,-0.018,0.039,-0.006,-0.001,-0.015,0.038,0.038,-0.009,0.026,0.017,0.056)
V2=c(-0.014,0.001,0.004,-0.002,0.022,0.019,0.023,-0.023,0.030,-0.085,-0.007,-0.027,0.100,0.058,0.108,0.055,0.132,0.115,0.084,0.046,0.102,0.121,0.036,0.019,0.066,0.049,-0.011,0.020,0.023,0.011,0.041,0.009,-0.009,-0.023,-0.036,0.031,0.012,0.026,-0.011,0.009,-0.027,-0.033,-0.054,-0.004,-0.040,-0.048,-0.009,0.023,-0.028,0.022,0.090,0.060,0.040,0.003,-0.011,0.030,0.107,0.025,0.084,0.036,0.074,0.065,0.078,0.011,0.058,0.092,0.083,0.080,0.039,0.000,-0.027,0.035,0.011,0.004,0.023,-0.033,-0.060,-0.049,-0.101,-0.033,-0.105,-0.042,-0.088,-0.086,-0.093,-0.085,-0.028,-0.046,-0.045,-0.052,-0.009,-0.066,-0.073,-0.067,0.011,-0.057,-0.087,-0.066,-0.103,-0.075,0.003,-0.021,0.010,-0.013,0.021,0.020,0.084,0.028,0.127,0.050,0.104,0.097,0.075,0.021,0.057,0.095,0.080,0.077,0.086,0.110,0.054,0.016,0.105,0.065,0.046,0.047,0.072,0.058,0.092,0.063,0.033,0.087,0.036,0.049,0.093,0.008,0.064,0.068,0.040,0.049,0.035,0.042,0.045,0.021,0.056,0.007,0.026,0.067,0.046,0.088,0.084,0.070,0.037,0.079,0.065,0.074,0.077,0.023,0.094,0.061,0.096,0.068,0.067,0.091,0.061,0.069,0.090,0.046,0.057,0.011,-0.018,0.005,0.001,-0.023,-0.087,0.010,0.023,-0.025,-0.040,-0.059,-0.063,-0.075,-0.136,-0.078,-0.102,-0.128,-0.116,-0.091,-0.136,-0.083,-0.115,-0.063,-0.055,-0.080,-0.093,-0.099,-0.053,-0.042,-0.011,-0.034,-0.027,-0.042,-0.022,-0.008,-0.033,-0.039,-0.036,0.019,0.036,-0.002,0.000,-0.021,0.060,0.030,0.073,0.080,0.061,0.046,0.062,0.010,0.034,0.103,0.107,0.016,0.080,0.067,0.007,0.060,0.021,-0.026,0.008,0.051,0.030,0.001,-0.036,-0.047,0.000,0.006,0.006,0.013,0.009,0.019,0.009,-0.086,-0.020,0.018,0.039,0.014,0.011,0.052,0.031,0.095,0.047,0.065,0.114,0.086,0.102,0.037,0.039,0.060,0.024,0.091,0.058,0.065,0.060,0.045,0.031,0.062,0.047,0.043,0.057,0.032,0.057,0.051,0.019,0.056,0.024,-0.003,0.023,-0.013,-0.032,-0.022,-0.064,-0.021,-0.050,-0.063,-0.090,-0.082,-0.076,-0.077,-0.042,-0.060,-0.010,-0.060,-0.069,-0.028,-0.071,-0.046,-0.020,-0.074,0.080,0.071,0.065,0.079,0.065,0.039,0.061,0.154,0.072,0.067,0.133,0.106,0.080,0.047,0.053,0.110,0.080,0.122,0.075,0.052,0.034,0.081,0.118,0.079,0.101,0.053,0.082,0.036,0.033,0.026,0.002,-0.002,0.020,0.087,0.021,0.034,0.003,-0.021,0.016,-0.009,-0.045,-0.043,-0.020,0.027,0.008,-0.006,0.043,0.045,0.014,0.053,0.083,0.113,0.091,0.028,0.060,0.040,0.019,0.114,0.126,0.090,0.046,0.089,0.029,0.030,0.010,0.045,0.040,0.072,-0.033,-0.008,0.014,-0.018,-0.004,-0.037,0.015,-0.021,-0.015)
bindistances=c(1.37,1.62,1.87,2.12,2.37,2.62,2.87,3.12,3.37,3.62,3.87,4.12,4.37,4.62,4.87,5.12,5.37,5.62,5.87,6.12,6.37,6.62,6.87,7.12,7.37,7.62,7.87,8.12)
Then, as a representation of currents:
AA=14
x11()
par(mfrow=c(4,1))
plotSticks(x=seq(from=(1),
to=(377),
by=(1)),
u=U1,
v=V1,
yscale=ysc,xlab='',ylab='',xaxt='n',yaxt='n',col=(rep('black',384)))
axis(side=1)
plotSticks(x=seq(from=(1),
to=(377),
by=(1)),
u=U2,
v=V2,
yscale=ysc,xlab='',ylab='',xaxt='n',yaxt='n',col=(rep('black',384)))
plotSticks(x=seq(from=(1),
to=(377),
by=(1)),
u=U2,
v=V2,
yscale=ysc,xlab='',ylab='',xaxt='n',yaxt='n',col=(rep('black',384)))
plotSticks(x=seq(from=(1),
to=(377),
by=(1)),
u=U2,
v=V2,
yscale=ysc,xlab='',ylab='',xaxt='n',yaxt='n',col=(rep('black',384)))
In order to simplify the representation, the three last plots are based on the same data.

Rotating Multi-Dimensional Arrays

So I want to compare one 2-dimensional array with another 2-dimensional array (acctually portion of another larger 2-dimensional arrays). What I need to do is to compare the first array with the second, but I also need to compare it from multiple angles, rotating one of them if you will.
I'm writing this in c++ and I'm using vectors (in case there is a specific algorithm or function for these that would help)
Here's an example of what I need to be able to do with this:
Take this map:
0001000
0001000
0001000
0001111
0000000
Compare it to this (which means if 1 is road and 0 is grass, this would help
me find 'turns' in the road):
010
110
000
Comparing it like that won't yield any results, BUT, if I rotate it to 180
degrees:
010
011
000
It fits.
More specifally I will compare a whole bunch of small arrays to the large array. I will not compare every location on the large array, only pick a location at random and a small array at random, rotate the small array to all 4 sides and see if they match. I will repeat this a few hundred times to find a decent sample of locations where a random selected sample of small maps compare positively to the large map.
Basically... :)
Atm I'm trying to figure it out, but I don't want to reinvent a wheel if I can help it.
(UPDATE: Close to solving this! I realised that I acctually need to rotate the lesser grid 8 times, I need to match every mirror!
UPDATE2: lol I solved it wtf. Will post as soon as I understand what the code acctually does, might as well. 5 AM I'm crazy like this!)

Lol. Interesting problem. I want to try it too. Try reading into rotation matrices. They're a little straightforward when it comes to rotating the entire matrices, and if the angle of rotation greatly concerns you.
http://en.wikipedia.org/wiki/Rotation_matrix