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I cannot understand how to identify a function with a log time. The most common attributes of logarithmic running-time function are that: the choice of the next element on which to perform some action is one of several possibilities, and only one will need to be chosen. or the elements on which the action is performed are digits of n This is ...


Many good answers have already been posted to this question, but I believe we really are missing an important one - namely, the illustrated answer. What does it mean to say that the height of a complete binary tree is O(log n)? The following drawing depicts a binary tree. Notice how each level contains the double number of nodes compared to the level ...


function log10(val) { return Math.log(val) / Math.LN10; }


O(log n) basically means time goes up linearly while the n goes up exponentially. So if it takes 1 second to compute 10 elements, it will take 2 seconds to compute 100 elements, 3 seconds to compute 1000 elements, and so on.


You can use the Axes.set_yscale method. That allows you to change the scale after the Axes object is created. That would also allow you to build a control to let the user pick the scale if you needed to. The relevant line to add is: ax.set_yscale('log') You can use 'linear' to switch back to a linear scale. Here's what your code would look like: from ...


Binary tree is a special case where a problem of size n is divided into sub-problem of size n/2. Let me show you how to calculate the height of tree in which a problem is divided into subproblems of size b until we recursively reach a problem of size 1.


First of all, it's not very tidy to mix pylab and pyplot code. What's more, pyplot style is preferred over using pylab. Here is a slightly cleaned up code, using only pyplot functions: from matplotlib import pyplot a = [ pow(10,i) for i in range(10) ] pyplot.subplot(2,1,1) pyplot.plot(a, color='blue', lw=2) pyplot.yscale('log') pyplot.show() The ...


I have to agree that it's pretty weird the first time you see an O(log n) algorithm... where on earth does that logarithm come from? However, it turns out that there's several different ways that you can get a log term to show up in big-O notation. Here are a few: Repeatedly dividing by a constant Take any number n; say, 16. How many times can you ...


You can use a function like this: function logslider(position) { // position will be between 0 and 100 var minp = 0; var maxp = 100; // The result should be between 100 an 10000000 var minv = Math.log(100); var maxv = Math.log(10000000); // calculate adjustment factor var scale = (maxv-minv) / (maxp-minp); return Math.exp(minv + ...


Logarithmic running time (O(log n)) essentially means that the running time grows in proportion to the logarithm of the input size - as an example, if 10 items takes at most some amount of time x, and 100 items takes at most, say, 2x, and 10,000 items takes at most 4x, then it's looking like an O(log n) time complexity.


I finally found some time to do some experiments in order to understand the difference between them. Here's what I discovered: log only allows positive values, and lets you choose how to handle negative ones (mask or clip). symlog means symmetrical log, and allows positive and negative values. symlog allows to set a range around zero within the plot will ...


It's good to know that but also know that math.log takes an optional second argument which allows you to specify the base: In [22]: import math In [23]: math.log? Type: builtin_function_or_method Base Class: <type 'builtin_function_or_method'> String Form: <built-in function log> Namespace: Interactive Docstring: log(x[, base]) ...


If you are on a recent-ish x86 or x86-64 platform (and you probably are), use the bsr instruction which will return the position of the highest set bit in an unsigned integer. It turns out that this is exactly the same as log2(). Here is a short C or C++ function that invokes bsr using inline ASM: #include <stdint.h> static inline uint32_t ...


You can think of O(log N) intuitively by saying the time is proportional to the number of digits in N. If an operation performs constant time work on each digit or bit of an input, the whole operation will take time proportional to the number of digits or bits in the input, not the magnitude of the input; thus, O(log N) rather than O(N). If an operation ...


O(log log n) terms can show up in a variety of different places, but there are typically two main routes that will arrive at this runtime. Shrinking by a Square Root As mentioned in the answer to the linked question, a common way for an algorithm to have time complexity O(log n) is for that algorithm to work by repeatedly cut the size of the input down by ...


If you had a function that takes: 1 millisecond to complete if you have 2 elements. 2 milliseconds to complete if you have 4 elements. 3 milliseconds to complete if you have 8 elements. 4 milliseconds to complete if you have 16 elements. ... n milliseconds to complete if you have 2**n elements. Then it takes log2(n) time. The Big O notation, loosely ...


Easy, just change the base by dividing by the log(10). There is even a constant to help you Math.log(num) / Math.LN10; which is the same as: Math.log(num) / Math.log(10);


This is the function that I use for this calculation: public static int binlog( int bits ) // returns 0 for bits=0 { int log = 0; if( ( bits & 0xffff0000 ) != 0 ) { bits >>>= 16; log = 16; } if( bits >= 256 ) { bits >>>= 8; log += 8; } if( bits >= 16 ) { bits >>>= 4; log += 4; } if( bits >= 4 ) ...


A histogram is a poor-man's density estimate. Note that in your call to hist() using default arguments, you get frequencies not probabilities -- add ,prob=TRUE to the call if you want probabilities. As for the log axis problem, don't use 'x' if you do not want the x-axis transformed: plot(mydata_hist$count, log="y", type='h', lwd=10, lend=2) gets you ...


You simply need to use semilogy instead of plot: from pylab import * import matplotlib.pyplot as pyplot a = [ pow(10,i) for i in range(10) ] fig = pyplot.figure() ax = fig.add_subplot(2,1,1) line, = ax.semilogy(a, color='blue', lw=2) show()


Math.log(x)/Math.log(2) That's the usual accepted way. There isn't a built in function for log2, but making one is trivial and will give your code better cohesion. (if you remember from math class, log10 x = ln x / ln 10) :D


You can simply divide the logarithm of your value, and the logarithm of the desired base, also you could override the Math.log method to accept an optional base argument: Math.log = (function() { var log = Math.log; return function(n, base) { return log(n)/(base ? log(base) : 1); }; })(); Math.log(5, 10);


It looks like Java actually has a log10 function: Math.log10(x) Otherwise, just use math: Math.log(x) / Math.log(10) http://docs.oracle.com/javase/7/docs/api/java/lang/Math.html


The best way I've always had to mentally visualize an algorithm that runs in O(log n) is as follows: If you increase the problem size by a multiplicative amount (i.e. multiply its size by 10), the work is only increased by an additive amount. Applying this to your binary tree question so you have a good application: if you double the number of nodes in a ...


You provided the code snippet for (int i = 10; i < 10000000; i *= 10) { System.out.println(((int) (Math.log10(i)) + 1) + " " + ((int) (Math.log(i) / Math.log(10)) + 1)); } to illustrate your question. Just remove the casts to int and run the loop again. You will receive 2.0 2.0 3.0 3.0 4.0 3.9999999999999996 5.0 5.0 6.0 6.0 7.0 ...


You can use this method instead: int targetlevel = 0; while (index >>= 1) ++targetlevel; Note: this will modify index. If you need it unchanged, create another temporary int. The corner case is when index is 0. You probably should check it separately and throw an exception or return an error if index == 0.


You can calculate a logarithm in a given base by calculating two logarithms in an arbitrary base, using the following equation: log_b (x) = log_k (x) / log_k (b) As the windows calculator got a ln button, which stands for the natural logarithm (that is, log in basis e,) then you can press 125, ln, /, 5, ln, and get the desired result. For bonus points, ...


For a general example that is understandable: screw merge sort for now, look at binary search. Pick a number between 1 and 1000. I guess 500. You say "higher". I guess 750. You say "lower." I choose 625... Clearly my search is not going to take 1000 guesses (order n). I chop my search domain in half each time and take 10 guesses or less (lg(1000) is about ...


pow is built into the language(not part of the math library). The problem is that you haven't imported math. Try this: import math math.sqrt(4)


Another option would be to use the ggplot2 package. ggplot(mydata, aes(x = V3)) + geom_histogram() + scale_x_log()

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