Many sites offer some statistics like "The hottest topics in the last 24h". For example, Topix.com shows this in its section "News Trends". There, you can see the topics which have the fastest growing number of mentions.

I want to compute such a "buzz" for a topic, too. How could I do this? The algorithm should weight the topics which are always hot less. The topics which normally (almost) no one mentions should be the hottest ones.

Google offers "Hot Trends", topix.com shows "Hot Topics", fav.or.it shows "Keyword Trends" - all these services have one thing in common: They only show you upcoming trends which are abnormally hot at the moment.

Terms like "Britney Spears", "weather" or "Paris Hilton" won't appear in these lists because they're always hot and frequent. This article calls this "The Britney Spears Problem".

My question: How can you code an algorithm or use an existing one to solve this problem? Having a list with the keywords searched in the last 24h, the algorithm should show you the 10 (for example) hottest ones.

I know, in the article above, there is some kind of algorithm mentioned. I've tried to code it in PHP but I don't think that it'll work. It just finds the majority, doesn't it?

I hope you can help me (coding examples would be great).

  • 1
    This is exactly the same question and he even states that! Why are people upvoting it! May 5, 2009 at 18:55
  • 3
    I'm a little confused about which type of result you are looking for. The article seems to indicate that "Britney Spears" will consistently be found in the "Hot" list because so many people search for that term, but your question states that it will NOT appear in the list because the number of searches for that term do not increase much over time (they remain high, but steady). Which result are you trying to acheive? Should "Britney Spears" rank high or low?
    – e.James
    May 5, 2009 at 19:00
  • 1
    @eJames, "Britney Spears" shouldn't rank high because she is consistantly a high search term and he is looking for search terms with a high velocity.
    – mmcdole
    May 5, 2009 at 19:34
  • 1
    Voting for reopen: This is a follow-up question on the original one, asking about a special problem that comes up when trying to solve the original problem. May 6, 2009 at 23:50
  • 1
    Not an exact duplicate, not even a near-duplicate. This question is about solving a specific problem with a specific algorithm. May 7, 2009 at 1:58

11 Answers 11


This problem calls for a z-score or standard score, which will take into account the historical average, as other people have mentioned, but also the standard deviation of this historical data, making it more robust than just using the average.

In your case a z-score is calculated by the following formula, where the trend would be a rate such as views / day.

z-score = ([current trend] - [average historic trends]) / [standard deviation of historic trends]

When a z-score is used, the higher or lower the z-score the more abnormal the trend, so for example if the z-score is highly positive then the trend is abnormally rising, while if it is highly negative it is abnormally falling. So once you calculate the z-score for all the candidate trends the highest 10 z-scores will relate to the most abnormally increasing z-scores.

Please see Wikipedia for more information, about z-scores.


from math import sqrt

def zscore(obs, pop):
    # Size of population.
    number = float(len(pop))
    # Average population value.
    avg = sum(pop) / number
    # Standard deviation of population.
    std = sqrt(sum(((c - avg) ** 2) for c in pop) / number)
    # Zscore Calculation.
    return (obs - avg) / std

Sample Output

>>> zscore(12, [2, 4, 4, 4, 5, 5, 7, 9])
>>> zscore(20, [21, 22, 19, 18, 17, 22, 20, 20])
>>> zscore(20, [21, 22, 19, 18, 17, 22, 20, 20, 1, 2, 3, 1, 2, 1, 0, 1])
>>> zscore(2, [21, 22, 19, 18, 17, 22, 20, 20, 1, 2, 3, 1, 2, 1, 0, 1])
>>> zscore(9, [1, 2, 0, 3, 1, 3, 1, 2, 9, 8, 7, 10, 9, 5, 2, 4, 1, 1, 0])


  • You can use this method with a sliding window (i.e. last 30 days) if you wish not to take to much history into account, which will make short term trends more pronounced and can cut down on the processing time.

  • You could also use a z-score for values such as change in views from one day to next day to locate the abnormal values for increasing/decreasing views per day. This is like using the slope or derivative of the views per day graph.

  • If you keep track of the current size of the population, the current total of the population, and the current total of x^2 of the population, you don't need to recalculate these values, only update them and hence you only need to keep these values for the history, not each data value. The following code demonstrates this.

      from math import sqrt
      class zscore:
          def __init__(self, pop = []):
              self.number = float(len(pop))
              self.total = sum(pop)
              self.sqrTotal = sum(x ** 2 for x in pop)
          def update(self, value):
              self.number += 1.0
              self.total += value
              self.sqrTotal += value ** 2
          def avg(self):
              return self.total / self.number
          def std(self):
              return sqrt((self.sqrTotal / self.number) - self.avg() ** 2)
          def score(self, obs):
              return (obs - self.avg()) / self.std()
  • Using this method your work flow would be as follows. For each topic, tag, or page create a floating point field, for the total number of days, sum of views, and sum of views squared in your database. If you have historic data, initialize these fields using that data, otherwise initialize to zero. At the end of each day, calculate the z-score using the day's number of views against the historic data stored in the three database fields. The topics, tags, or pages, with the highest X z-scores are your X "hotest trends" of the day. Finally update each of the 3 fields with the day's value and repeat the process next day.

New Addition

Normal z-scores as discussed above do not take into account the order of the data and hence the z-score for an observation of '1' or '9' would have the same magnitude against the sequence [1, 1, 1, 1, 9, 9, 9, 9]. Obviously for trend finding, the most current data should have more weight than older data and hence we want the '1' observation to have a larger magnitude score than the '9' observation. In order to achieve this I propose a floating average z-score. It should be clear that this method is NOT guaranteed to be statistically sound but should be useful for trend finding or similar. The main difference between the standard z-score and the floating average z-score is the use of a floating average to calculate the average population value and the average population value squared. See code for details:


class fazscore:
    def __init__(self, decay, pop = []):
        self.sqrAvg = self.avg = 0
        # The rate at which the historic data's effect will diminish.
        self.decay = decay
        for x in pop: self.update(x)
    def update(self, value):
        # Set initial averages to the first value in the sequence.
        if self.avg == 0 and self.sqrAvg == 0:
            self.avg = float(value)
            self.sqrAvg = float((value ** 2))
        # Calculate the average of the rest of the values using a 
        # floating average.
            self.avg = self.avg * self.decay + value * (1 - self.decay)
            self.sqrAvg = self.sqrAvg * self.decay + (value ** 2) * (1 - self.decay)
        return self
    def std(self):
        # Somewhat ad-hoc standard deviation calculation.
        return sqrt(self.sqrAvg - self.avg ** 2)
    def score(self, obs):
        if self.std() == 0: return (obs - self.avg) * float("infinity")
        else: return (obs - self.avg) / self.std()

Sample IO

>>> fazscore(0.8, [1, 1, 1, 1, 1, 1, 9, 9, 9, 9, 9, 9]).score(1)
>>> fazscore(0.8, [1, 1, 1, 1, 1, 1, 9, 9, 9, 9, 9, 9]).score(9)
>>> fazscore(0.9, [2, 4, 4, 4, 5, 5, 7, 9]).score(12)
>>> fazscore(0.9, [2, 4, 4, 4, 5, 5, 7, 9]).score(22)
>>> fazscore(0.9, [21, 22, 19, 18, 17, 22, 20, 20]).score(20)
>>> fazscore(0.9, [21, 22, 19, 18, 17, 22, 20, 20, 1, 2, 3, 1, 2, 1, 0, 1]).score(20)
>>> fazscore(0.9, [21, 22, 19, 18, 17, 22, 20, 20, 1, 2, 3, 1, 2, 1, 0, 1]).score(2)
>>> fazscore(0.9, [1, 2, 0, 3, 1, 3, 1, 2, 9, 8, 7, 10, 9, 5, 2, 4, 1, 1, 0]).score(9)
>>> fazscore(0.8, [40] * 200).score(1)


As David Kemp correctly pointed out, if given a series of constant values and then a zscore for an observed value which differs from the other values is requested the result should probably be non-zero. In fact the value returned should be infinity. So I changed this line,

if self.std() == 0: return 0


if self.std() == 0: return (obs - self.avg) * float("infinity")

This change is reflected in the fazscore solution code. If one does not want to deal with infinite values an acceptable solution could be to instead change the line to:

if self.std() == 0: return obs - self.avg
  • 1
    No, your code has one small mistake, on the following line. $z_score = $hits_today-($average_hits_per_day/$standard_deviation); It should be: $z_score = ($hits_today-$average_hits_per_day)/$standard_deviation; Note the change in parentheses.
    – Nixuz
    May 6, 2009 at 18:50
  • 1
    @nixuz - am I missing something: fazscore(0.8,map(lambda x:40,range(0,200))).score(1) == 0 (for any values)? Dec 17, 2010 at 5:03
  • 1
    @Nixus - Thought I might dig this one up from the grave. Could you re-post the PHP implementation of this? The paste links do not seem to be working...thanks!
    – Drewness
    Apr 23, 2013 at 19:51
  • 1
    The decay here is counter intuitive; if you would enter 2 values, say [10, 20] with a decay of 0.8, the AVG is 10*0.8+20*0.2=12. You would expect a value above 15, since 20 should have more weight than 10 if there is decay. There is a much better alternative available using a weighted average in numpy.average, where you create a parallel list with weights. For instance: data=range(10,30,10) decay=0.8 decay_weights = [decay**a for a in range(len(data),0,-1)] print np.average(data,weights=decay_weights)
    – Jeroen
    Jun 1, 2018 at 9:09
  • 2
    Using a distribution that fits your data would be best. Normally distributed data is just an assumption but you should measure this base on your uses case.
    – Nixuz
    May 7, 2019 at 4:26

You need an algorithm that measures the velocity of a topic - or in other words, if you graph it you want to show those that are going up at an incredible rate.

This is the first derivative of the trend line, and it is not difficult to incorporate as a weighted factor of your overall calculation.


One technique you'll need to do is to normalize all your data. For each topic you are following, keep a very low pass filter that defines that topic's baseline. Now every data point that comes in about that topic should be normalized - subtract its baseline and you'll get ALL of your topics near 0, with spikes above and below the line. You may instead want to divide the signal by its baseline magnitude, which will bring the signal to around 1.0 - this not only brings all signals in line with each other (normalizes the baseline), but also normalizes the spikes. A britney spike is going to be magnitudes larger than someone else's spike, but that doesn't mean you should pay attention to it - the spike may be very small relative to her baseline.


Once you've normalized everything, figure out the slope of each topic. Take two consecutive points, and measure the difference. A positive difference is trending up, a negative difference is trending down. Then you can compare the normalized differences, and find out what topics are shooting upward in popularity compared to other topics - with each topic scaled appropriate to it's own 'normal' which may be magnitudes of order different from other topics.

This is really a first-pass at the problem. There are more advanced techniques which you'll need to use (mostly a combination of the above with other algorithms, weighted to suit your needs) but it should be enough to get you started.

Regarding the article

The article is about topic trending, but it's not about how to calculate what's hot and what's not, it's about how to process the huge amount of information that such an algorithm must process at places like Lycos and Google. The space and time required to give each topic a counter, and find each topic's counter when a search on it goes through is huge. This article is about the challenges one faces when attempting such a task. It does mention the Brittney effect, but it doesn't talk about how to overcome it.

As Nixuz points out this is also referred to as a Z or Standard Score.

  • Thanks! I would do pseudo code, but I don't have the time right now. Maybe later, or perhaps someone else will take these concepts and implement it...
    – Adam Davis
    May 5, 2009 at 19:48
  • Thank you very much, Adam Davis! If Nixuz really described the same, I think I've got a solution in PHP: paste.bradleygill.com/index.php?paste_id=9206 Do you think this code is right?
    – caw
    May 6, 2009 at 19:07
  • Shouldn't it be acceleration of topic rather than velocity? Check out the last answer
    – Sap
    May 31, 2013 at 9:36

Chad Birch and Adam Davis are correct in that you will have to look backward to establish a baseline. Your question, as phrased, suggests that you only want to view data from the past 24 hours, and that won't quite fly.

One way to give your data some memory without having to query for a large body of historical data is to use an exponential moving average. The advantage of this is that you can update this once per period and then flush all old data, so you only need to remember a single value. So if your period is a day, you have to maintain a "daily average" attribute for each topic, which you can do by:

a_n = a_(n-1)*b + c_n*(1-b)

Where a_n is the moving average as of day n, b is some constant between 0 and 1 (the closer to 1, the longer the memory) and c_n is the number of hits on day n. The beauty is if you perform this update at the end of day n, you can flush c_n and a_(n-1).

The one caveat is that it will be initially sensitive to whatever you pick for your initial value of a.


If it helps to visualize this approach, take n = 5, a_0 = 1, and b = .9.

Let's say the new values are 5,0,0,1,4:

a_0 = 1
c_1 = 5 : a_1 = .9*1 + .1*5 = 1.4
c_2 = 0 : a_2 = .9*1.4 + .1*0 = 1.26
c_3 = 0 : a_3 = .9*1.26 + .1*0 = 1.134
c_4 = 1 : a_4 = .9*1.134 + .1*1 = 1.1206
c_5 = 4 : a_5 = .9*1.1206 + .1*5 = 1.40854

Doesn't look very much like an average does it? Note how the value stayed close to 1, even though our next input was 5. What's going on? If you expand out the math, what you get that:

a_n = (1-b)*c_n + (1-b)*b*c_(n-1) + (1-b)*b^2*c_(n-2) + ... + (leftover weight)*a_0

What do I mean by leftover weight? Well, in any average, all weights must add to 1. If n were infinity and the ... could go on forever, then all weights would sum to 1. But if n is relatively small, you get a good amount of weight left on the original input.

If you study the above formula, you should realize a few things about this usage:

  1. All data contributes something to the average forever. Practically speaking, there is a point where the contribution is really, really small.
  2. Recent values contribute more than older values.
  3. The higher b is, the less important new values are and the longer old values matter. However, the higher b is, the more data you need to water down the initial value of a.

I think the first two characteristics are exactly what you are looking for. To give you an idea of simple this can be to implement, here is a python implementation (minus all the database interaction):

>>> class EMA(object):
...  def __init__(self, base, decay):
...   self.val = base
...   self.decay = decay
...   print self.val
...  def update(self, value):
...   self.val = self.val*self.decay + (1-self.decay)*value
...   print self.val
>>> a = EMA(1, .9)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
>>> a.update(10)
  • 1
    This is also known as an infinite impulse response filter (IIR)
    – Adam Davis
    May 5, 2009 at 19:37
  • @Adam Really? I'm not familiar with them. Is it a special case of an IIR? The articles I'm skimming don't seem to be providing formulas that reduce down to an exponential moving average in the simple case. May 6, 2009 at 5:33
  • 1
    Thank you very much, David Berger! If it works, it would be a great addition to the other answers! I have some questions, though. I hope you can answer them: 1) Does the factor b define how fast the old data is losing weight? 2) Will this approach give approximately equivalent results compared to simply store the old data and calculate the average? 3) Is this your formula in words? $average_value = $old_average_value * $smoothing_factor + $hits_today * (1-$smoothing_factor)
    – caw
    May 6, 2009 at 17:50
  • Points 1 and 3 are correct. See my edit for a bit of a nuanced discussion of 2. May 6, 2009 at 19:34
  • 1
    Maybe I am missing something, but I fail to understand how you can reasonably use a moving average to solve this problem. Once you have calculated your moving average for your trends, how do you know which trend is rising the fastest in comparison to the others? Could you add some more information about how this solves the initial problem asked. Thanks.
    – Nixuz
    May 6, 2009 at 23:28

Typically "buzz" is figured out using some form of exponential/log decay mechanism. For an overview of how Hacker News, Reddit, and others handle this in a simple way, see this post.

This doesn't fully address the things that are always popular. What you're looking for seems to be something like Google's "Hot Trends" feature. For that, you could divide the current value by a historical value and then subtract out ones that are below some noise threshold.

  • Yes, Google's Hot Trends is exactly what I'm looking for. What should the historical value be? The average value of the last 7 days for example?
    – caw
    May 2, 2009 at 18:49
  • 1
    It depends on how volatile your data is. You could start with a 30 day average. If it's a cyclical thing (e.g. Kentucky Derby) then it might make sense to do yearly comparisons. I'd experiment and see what works best in practice.
    – Jeff Moser
    May 3, 2009 at 23:02

I think they key word you need to notice is "abnormally". In order to determine when something is "abnormal", you have to know what is normal. That is, you're going to need historical data, which you can average to find out the normal rate of a particular query. You may want to exclude abnormal days from the averaging calculation, but again that'll require having enough data already, so that you know which days to exclude.

From there, you'll have to set a threshold (which would require experimentation, I'm sure), and if something goes outside the threshold, say 50% more searches than normal, you can consider it a "trend". Or, if you want to be able to find the "Top X Trendiest" like you mentioned, you just need to order things by how far (percentage-wise) they are away from their normal rate.

For example, let's say that your historical data has told you that Britney Spears usually gets 100,000 searches, and Paris Hilton usually gets 50,000. If you have a day where they both get 10,000 more searches than normal, you should be considering Paris "hotter" than Britney, because her searches increased 20% more than normal, while Britney's were only 10%.

God, I can't believe I just wrote a paragraph comparing "hotness" of Britney Spears and Paris Hilton. What have you done to me?

  • Thanks, but it would be a bit too easy to order them just by their procentual increasing, wouldn't it?
    – caw
    May 6, 2009 at 17:37

I was wondering if it is at all possible to use regular physics acceleration formula in such a case?

v2-v1/t or dv/dt

We can consider v1 to be initial likes/votes/count-of-comments per hour and v2 to be current "velocity" per hour in last 24 hours?

This is more like a question than an answer, but seems it may just work. Any content with highest acceleration will be the trending topic...

I am sure this may not solve Britney Spears problem :-)

  • It will work, as it just calculates the vote/like increasement per time, and this is what we need. It could solve the "Britney spears problem" in parts because this search term has always a high v1 and would need a very high v2 to be considered "trending". However, there are probably better and more sophisticated formulas and algorithms to do this. Nevertheless, it is a basic working example.
    – caw
    May 27, 2013 at 12:33
  • In a context where you always need to have something in the "trending" feed, this is perfect. Something like an Explore tab where you list what is the best on the platform right now. Using a different algo, you may end up having an empty results set.
    – kilianc
    Jan 14, 2015 at 10:47

probably a simple gradient of topic frequency would work -- large positive gradient = growing quickly in popularity.

the easiest way would be to bin the number of searched each day, so you have something like

searches = [ 10, 7, 14, 8, 9, 12, 55, 104, 100 ]

and then find out how much it changed from day to day:

hot_factor = [ b-a for a, b in zip(searches[:-1], searches[1:]) ]
# hot_factor is [ -3, 7, -6, 1, 3, 43, 49, -4 ]

and just apply some sort of threshold so that days where the increase was > 50 are considered 'hot'. you could make this far more complicated if you'd like, too. rather than absolute difference you can take the relative difference so that going from 100 to 150 is considered hot, but 1000 to 1050 isn't. or a more complicated gradient that takes into account trends over more than just one day to the next.

  • Thank you. But I don't know exactly what a gradient is and how I can work with it. Sorry!
    – caw
    Apr 26, 2009 at 19:30
  • Thanks. So I have to built a vector containing the daily frequency, right? The relative values would be be better, I'm sure. Example: A growth from 100 to 110 is not as good as a growth from 1 to 9, I would say. But isn't there a vector function which I can use to find the hottest topics? Only evaluating the relative values wouldn't be enought, would it? A growth from 100 to 200 (100%) is not as good as a growth from 20,000 to 39,000!?
    – caw
    Apr 27, 2009 at 19:26
  • What kind of web site are you adding this to? @Autoplectic's suggestion to count the change in searches day to day won't scale well for something like a popular forum, where you have thousands of topics with new ones being defined each day.
    – Quantum7
    Apr 28, 2009 at 19:27
  • You're right, I need an algorithm for huge amounts of data, thousands of topics per hour.
    – caw
    May 2, 2009 at 18:50
  • this is a poor strategy. this way, a total increase of 50 searches about Britney Spears is as hot as +50 searches about a new referendum in Europe. Jul 5, 2016 at 11:59

I had worked on a project, where my aim was finding Trending Topics from Live Twitter Stream and also doing sentimental analysis on the trending topics (finding if Trending Topic positively/negatively talked about). I've used Storm for handling twitter stream.

I've published my report as a blog: http://sayrohan.blogspot.com/2013/06/finding-trending-topics-and-trending.html

I've used Total Count and Z-Score for the ranking.

The approach that I've used is bit generic, and in the discussion section, I've mentioned that how we can extend the system for non-Twitter Application.

Hope the information helps.


You could use log-likelihood-ratios to compare the current date with the last month or year. This is statistically sound (given that your events are not normally distributed, which is to be assumed from your question).

Just sort all your terms by logLR and pick the top ten.

public static void main(String... args) {
    TermBag today = ...
    TermBag lastYear = ...
    for (String each: today.allTerms()) {
        System.out.println(logLikelihoodRatio(today, lastYear, each) + "\t" + each);

public static double logLikelihoodRatio(TermBag t1, TermBag t2, String term) {
    double k1 = t1.occurrences(term); 
    double k2 = t2.occurrences(term); 
    double n1 = t1.size(); 
    double n2 = t2.size(); 
    double p1 = k1 / n1;
    double p2 = k2 / n2;
    double p = (k1 + k2) / (n1 + n2);
    double logLR = 2*(logL(p1,k1,n1) + logL(p2,k2,n2) - logL(p,k1,n1) - logL(p,k2,n2));
    if (p1 < p2) logLR *= -1;
    return logLR;

private static double logL(double p, double k, double n) {
    return (k == 0 ? 0 : k * Math.log(p)) + ((n - k) == 0 ? 0 : (n - k) * Math.log(1 - p));

PS, a TermBag is an unordered collection of words. For each document you create one bag of terms. Just count the occurrences of words. Then the method occurrences returns the number of occurrences of a given word, and the method size returns the total number of words. It is best to normalize the words somehow, typically toLowerCase is good enough. Of course, in the above examples you would create one document with all queries of today, and one with all queries of the last year.

  • Sorry, I don't understand the code. What are TermBags? It would be great if you could explain shortly what this code does.
    – caw
    May 5, 2009 at 18:29
  • 1
    A TermBag is a bag of terms, ie the class should be able to answer the total number of words in the text and the number of occurrences for each word.
    – akuhn
    May 12, 2009 at 16:56
  • Thanks @akuhn for the explanation and code snippet. I ported to Javascript and it works. I'm trying to understand the output: in some cases I see negative values (e.g. -4.679577112488872 AAPL) and in others, positive ones (e.g.3.4914628235919807 CRWD). Is the idea that the highest values are the ones trending? What are the negative values representing? Oct 14, 2021 at 18:14

If you simply look at tweets, or status messages to get your topics, you're going to encounter a lot of noise. Even if you remove all stop words. One way to get a better subset of topic candidates is to focus only on tweets/messages that share a URL, and get the keywords from the title of those web pages. And make sure you apply POS tagging to get nouns + noun phrases as well.

Titles of web pages usually are more descriptive and contain words that describe what the page is about. In addition, sharing a web page usually is correlated with sharing news that is breaking (ie if a celebrity like Michael Jackson died, you're going to get a lot of people sharing an article about his death).

I've ran experiments where I only take popular keywords from titles, AND then get the total counts of those keywords across all status messages, and they definitely remove a lot of noise. If you do it this way, you don't need a complex algorith, just do a simple ordering of the keyword frequencies, and you're halfway there.


The idea is to keep track of such things and notice when they jump significantly as compared to their own baseline.

So, for queries that have more than a certain threshhold, track each one and when it changes to some value (say almost double) of its historical value, then it is a new hot trend.

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