In my last post, I discussed the outstanding experiences I’ve had as an intern at SAS and some of the things that I’ve learned so far. I love working at SAS, and now that I’ve been here for a while, I can confidently say I’m contributing to the success of [...]
The post Interning at SAS: A Summer Adventure - Part 2 appeared first on SAS Analytics U Blog.
Every year, SAS ranks high on the Fortune 100 Best Companies to Work For list. The rankings are largely based on anonymous feedback from employees, who consistently rank SAS high on everything from executive communications to work-life balance. But SAS isn’t just a great place to work for professionals; it’s an [...]
The post Interning at SAS: A Summer Adventure - Part 1 appeared first on SAS Analytics U Blog.
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I recently saw an interesting PEW study showing the percent of each state's revenue that came from federal funds. They had some pretty nice graphs ... but just like jell-o, there's always room for more graphs, eh! Let's start with the map. Their map had an informative title, a reasonable gradient [...]
The post Which states rely the most on federal funds? appeared first on SAS Learning Post.
I recently saw an interesting PEW study showing the percent of each state's revenue that came from federal funds. They had some pretty nice graphs ... but just like jell-o, there's always room for more graphs, eh! Let's start with the map. Their map had an informative title, a reasonable gradient [...]
The post Which states rely the most on federal funds? appeared first on SAS Learning Post.
I use SAS Enterprise Guide every day, and for a wide variety of tasks. As a result, I have a huge collection of project files (EGP files) and SAS program files.
I have always relied on the "recently used" list in the File menu to provide me with quick access to the files I need to open. The File menu keeps two lists: one for project files and one for SAS programs. With a click into either list, you can see a simple list of all of the file names. Hover your cursor over any of the names to see a tooltip with the full path -- very useful in case you have similarly named files in different folders.
By default, the number of recently used items (SAS programs and projects) that the File menu tracks is just 6. That's not nearly as many as I need, so I've always changed that setting to the maximum, which has always been 15. You can find the setting in Tools→Options, General tab.
I recently learned that in SAS Enterprise Guide v7.12 and later, the maximum number of "recent files" to track was raised to 50! With more high-resolution displays in the field, even a long list of recent files can provide a convenient method to save a few clicks. I think 50 is a little high for me (I'll be reaching into last year's files), so I bumped my setting to 30.
Get EG to remember more files for you!
And don't forget the "jump list" in Windows 7 and later! Every program or project file that SAS Enterprise Guide opens is also added to this quick-access list that you can find on your Windows toolbar or Start menu. Here's an example of what that looks like:
The post Open recent files with fewer clicks in SAS Enterprise Guide appeared first on The SAS Dummy.
In a previous blog, I describe how there are a few new features related to report and page prompts in SAS Visual Analytics 8.1; namely the ability to configure cascading prompts in VA 8.1: Cascading Prompts as Report and Page Prompts.
In this blog, I will cover how to configure prompts, either report, page, or report canvas prompts, that use different data sources.
First, you must have two different data sources added to your Visual Analytics report. These data sources must have values that overlap that you wish to prompt on. All of the values do not need to map, but they must have some values in common if you wish to use a shared prompt.
In this example, we will prompt for Product Line. Let’s examine the column values:
I’ve color coded the values that I would like to map together. I see that the only values that match “out-of-the-box” is Game.
One work around to get all of the values to match will be to create a Custom Category and use that column for the mapping.
In a “real world” scenario, this may not be ideal. The cardinality of the two columns may be so large that you may have to go back to either the source data or ETL job to produce better matching values.
However, if you are using date columns as the mapping columns things are considerably easier as year, month, and quarter are standard values that match without extra steps.
Here is my new Custom Category that I will use for my mapping:
Here are my mappings now. I will be using Product Line (New) for the Insight Toys data source moving forward.
There are two different locations where you can add prompts, i.e. Control Objects, which means there are two different ways to configure prompts with different data sources:
1. Report and Page Prompts
2. Report Canvas Prompts
For this first example, I will configure a Button Bar object placed in the Page Prompt area to filter two different data sources. For the Button Bar’s Category Role, I will use the data source with the largest available selection, in this case, the Product Line (New) from Insight Toys.
Now let’s configure this button bar to filter both data sources. You must activate the button bar by clicking on it, then right-mouse click and select Edit data source mappings…
Then you simply have to pick your source table’s column to map to your target table’s column.
That’s it. The mapping is complete. Here is what the report would look like with different selections made for the button bar. Notice, that since I used the Insight Toys data source for the Role assignment, and it has more values than available in the Mega Corp data. If a selection is made where nothing matches in Mega Corp, as in the Gift example, then the Mega Corp bar chart is blank.
In this second example, I am going to use a List Control object within the report canvas to filter two different data sources. Again, I will use the Insight Toys’ Product Line (New) column as the List Role Category assignment since it has the most values.
Now to configure the list to filter both bar charts. Click on the list control object to activate the window. Then select the Actions pane, and use the Add button to select Add filter.
Then select both bar charts as the target of the filter Action.
Next, select the Map data option.
Select the source data’s column to map to the target data’s column. Use the + to add additional column mapping criteria.
Here is how the report would look with a few of the values selected from the list table. You can see how both Mega Corp and Insight Toys display overlapping values for Product Line but for any unique Product Lines, such as Gift, its values are only displayed on the Insight Toys bar chart.
Now you know how to configure your control objects for multiple data sources. This works no matter how many data sources you add to your report, simply use the Map data option and select the mappings between the source data and target data.
As I mentioned earlier, a frequently used application of mapping prompts for multiple data sources is for date columns. Here is a screenshot of one example using year and month. I also styled the button bar’s selected background and text color to coordinate with the graphs.
SAS Visual Analytics 8.1: Configuring prompts with different source data was published on SAS Users.
“I do not like this modern technology,” said my father-in-law. “It is making people too lazy. Things are too easy now.” He was referring to my grocery order. I was sitting in his kitchen in Reykjavik, Iceland, the day before my return to the United States. I had just explained [...]
Icelandic in-laws and inventory management: digital supply chain innovations was published on SAS Voices by Marcia Walker
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| Modern Data Science with R |
A classical problem in elementary probability asks for the expected lengths of line segments that result from randomly selecting k points along a segment of unit length. It is both fun and instructive to simulate such problems. This article uses simulation in the SAS/IML language to estimate solutions to the following problems:
You can find a discussion and solution to these problems on many websites, but I like the Cut-The-Knot.org website, which includes proofs and interactive Java applets.
You can simulate these problems in SAS by writing a DATA step or a SAS/IML program. I discuss the DATA step at the end of this article. The body of this article presents a SAS/IML simulation and constructed helper modules that solve the general problem. The simulation will do the following:
In many languages (including the SAS DATA step), you would write a loop that performs these operations for each random sample. You would then estimate the expected length by computing the mean value of the largest segment for each sample. However, in the SAS/IML language, you can use matrices instead of using a loop. Each sample of random points can be held in the column of a matrix. The lengths of the segments can also be held in a matrix. The largest segment for each trial is stored in a row vector.
The following SAS/IML modules help solve the general simulation problem for k random points. Because the points are ordered, the lengths of the segments are the differences between adjacent rows. You can use the DIF function for this computation, but the following program uses the DifOp module to construct a small difference operator, and it uses matrix multiplication to compute the differences.
proc iml; /* Independently sort column in a matrix. See http://blogs.sas.com/content/iml/2011/03/14/sorting-rows-of-a-matrix.html */ start SortCols(A); do i = 1 to ncol(A); v = A[ ,i]; call sort(v); A[ ,i] = v; /* get i_th col and sort it */ end; finish; /* Generate a random (k x NSim) matrix of points, then sort each column. */ start GenPts(k, NSim); x = j(k, NSim); /* allocate k x NSim matrix */ call randgen(x, "Uniform"); /* fill with random uniform in (0,1) */ if k > 1 then run SortCols(x); return x; finish; /* Return matrix for difference operator. See http://blogs.sas.com/content/iml/2017/07/24/difference-operators-matrices.html */ start DifOp(dim); D = j(dim-1, dim, 0); /* allocate zero matrix */ n = nrow(D); m = ncol(D); D[do(1,n*m, m+1)] = -1; /* assign -1 to diagonal elements */ D[do(2,n*m, m+1)] = 1; /* assign +1 to super-diagonal elements */ return D; finish; /* Find lengths of segments formed by k points in the columns of x. Assume each column of x is sorted and all points are in (0,1). */ start SegLengths(x); /* append 0 and 1 to top and bottom (respectively) of each column */ P = j(1, ncol(x), 0) // x // j(1, ncol(x), 1); D = DifOp(nrow(P)); /* construct difference operator */ return D*P; /* use difference operator to find lengths */ finish; P = {0.1 0.2 0.3, 0.3 0.8 0.5, 0.7 0.9 0.8 }; L = SegLengths(P); print L[label="Length (k=3)"]; |
The table shows the lengths of three different sets of points for k=3. The first column of P corresponds to points at locations {0.1, 0.3, 0.7}. These three points divide the interval [0, 1] into four segments of lengths 0.1, 0.2, 0.4, and 0.3. Similar computations hold for the other columns.
For k=1, the problem generates a random point in (0, 1) and asks for the expected length of the longer segment. Obviously the expected length is greater than 1/2, and you can read the Cut-The-Knot website to find a proof that shows that the expected length is 3/4 = 0.75.
The following SAS/IML statements generate one million random points and compute the larger of the segment lengths. The average value of the larger segments is computed and is very close to the expected value:
call randseed(54321); k = 1; NSim = 1E6; x = GenPts(k, NSim); /* simulations of 1 point dropped onto (0,1) */ L = SegLengths(x); /* lengths of segments */ Largest = L[<>, ]; /* max length among the segments */ mean = mean(Largest`); /* average of the max lengths */ print mean; |
You might not be familiar with the SAS/IML max subscript operator (<>) and the min subscript operator (><). These operators compute the minimum or maximum values for each row or column in a matrix.
For k=2, the problem generates two random points in (0, 1) and asks for the expected length of the longest segment. You can also ask for the average shortest length. The Cut-The-Knot website shows that the expected length for the longest segment is 11/18 = 0.611, whereas the expected length of the shortest segment is 2/18 = 0.111.
The following SAS/IML statements simulate choosing two random points on one million unit intervals. The program computes the one million lengths for the resulting longest and shortest segments. Again, the average values of the segments are very close to the expected values:
k = 2; NSim = 1E6; x = GenPts(k, NSim); /* simulations of 2 points dropped onto (0,1) */ L = SegLengths(x); /* lengths of segments */ maxL = L[<>, ]; /* max length among the segments */ meanMax = mean(maxL`); /* average of the max lengths */ minL = L[><, ]; /* min length among the segments */ meanMin = mean(minL`); /* average of the max lengths */ print meanMin meanMax; |
You can use the previous simulation to estimate the broken stick probability. Recall that three line segments can form a triangle provided that they satisfy the triangle inequality: the sum of the two smaller lengths must be greater than the third length. If you randomly choose two points in (0,1), the probability that the resulting three segments can form a triangle is 1/4, which is smaller than what most people would guess.
The vectors maxL and minL each contain one million lengths, so it is trivial to compute the vector of that contains the third lengths.
/* what proportion of randomly broken sticks form triangles? */ medL = 1 - maxL - minL; /* compute middle length */ isTriangle = (maxL <= minL + medL); /* do lengths satisfy triangle inequality? */ prop = mean(isTriangle`); /* proportion of segments that form a triangle */ print prop; |
As expected, about 0.25 of the simulations resulted in segments that satisfy the triangle inequality.
In conclusion, this article shows how to use the SAS/IML language to solve several classical problems in probability. By using matrices, you can run the simulation by using vectorized computations such as matrix multiplication finding the minimum or maximum values of columns. (However, I had to use a loop to sort the points. Bummer!)
If you want to try this simulation yourself in the DATA step, I suggest that you transpose the SAS/IML setup. Use arrays to hold the random points and use the CALL SORTN subroutine to sort the points. Use the LARGEST function and the SMALLEST function to compute the largest and smallest elements in an array. Feel free to post your solution (and any other thoughts) in the comments.
The post Random segments and broken sticks appeared first on The DO Loop.