Media recommendation engine - Single user system - How to start - algorithm

I want to implement a media recommendation engine. I saw a similar posts on this, but I think my requirements are bit different from those, so posting here.
Here is the deal.
I want to implement a recommendation engine for media players like VLC, which would be an engine that has to care for only single user. Like, it would be embedded in a media player on a PC which is typically used by single user. And it will start learning the likes and dislikes of the user and gradually learns what a user likes. Here it will not be able to find similar users for using their data for recommendation as its a single user system. So how to go about this?
Or you can consider it as a recommendation engine that has to be put in say iPods, which has to learn about a single user and recommend music/Movies from the collections it has.
I thought of start collecting the genre of music/movies (maybe even artist name) that user watches and recommend movies from the most watched Genre, but it look very crude, isn't it?
So is there any algorithms I can use or any resources I can refer up to?
Regards,
MicroKernel :)

What you're trying to do is quite challenging... particularly because it's still in the research stage and a lot of PHDs from reputable universities across the world are trying to get a good solution for that.
SO here are some things that you might need:
Data that you can analyze:
Lots, and lots, and lots of data!
It could be meta data about the media (name, duration, title, author, style, etc.)
Or you can try to do some crazy feature extraction from the media itself.
References to correlate the data to.
Since you can't get other users, you always need the user feedback.
If you don't want to annoy your user to death with feedback questions, then make your application connect to a central server so you can compare users.
An algorithm that can model your data sufficiently well.
If you have no experience at all, then try k-nearest neighbor (the simplest one).
Collaborative filtering
Pearson Correlation
Matrix Factorization/Decomposition
Singular value decomposition (SVD)
Ensemble learning <-- Allows you to combine multiple algorithms and take advantage of their strengths.
The winners of the NetFlix prize said this:
Predictive accuracy is substantially
improved when blending multiple
predictors. Our experience is that
most efforts should be concentrated in
deriving substantially different
approaches, rather than refining a
single technique. Consequently, our
solution is an ensemble of many
methods.
Conclusion:
There is no silver bullet for recommendation engines and it takes years of exploration to find a good combination of algorithms that produce sufficient results. :)

Related

What matching algorithm could I use?

I would need some help because I don't know what algorithm i could use for the following (I use python) :
Steve is 25 and he buys everyday orange juice
Maria is 23 and she likes to buy smoothies
Steve & Maria tastes are pretty much the same.
Juan is 16 and he only drinks sodas
Juan tastes are not the same as Steve and Maria.
====================================================
I would like to use a matching algorithm that will detect the users who have the same drink preference and a close age. To continue with the example, Steve and Maria would be matched together but not Juan. Which one should I use ?
I agree with #klutt that your task is pretty vague. There are two approaches that come to mind, but not knowing more details about your problem does limit the details I can provide in my answer that would help you. I am interpreting the question as if you are taking in raw text and might want to process more sentences that have very similar semantic and syntactical structure.
An algorithmic approach:
Assuming that your word choices are static in their semantic meaning (Maria is 23 ... Steve is 25), we can parse each sentence and identify tokens like is or and or same and essentially perform lexical analysis on the text... from here, you could continue thinking about how you would go about matching and so forth... but this is rather complicated...
Neural Network approach:
If you are taking in raw text in the form of sentences, it's a problem that's not straight forward to solve using a top-down algorithmic approach.
You could take an approach with neural networks that trains a model to solve your problem, but then again what you seem to be asking is quite complex since there are multiple "facts" within each sentence that are not semantically related. For example, your second sentence identifies that Maria is 23 but at the end of that sentence there is a comparison between Steve and Maria. And your first sentence only identifies Steve as 25.
Even if you chunk raw text into sentences, you would have to have a very fine tuned neural network architecture and a lot of training data to get remotely close to your goal.
Now, both of those solutions are very complex... but if you wanted to create an application that collects this data (via a form or prompt) and puts it into a structured format (like a json or xml object) to organize and store the data in memory (perhaps writing out to a database or file for persistent storage), that might be a good route to go down.
This can serve as a good lesson in how to think about data as well. It is one thing if you have a pool of thousands of sentences, just raw data that you need to organize for quantitative purposes (classic qualitative -> quantitative problems). It is another thing if you are going to be collecting this data. If you are going to be collecting data, having a program that collects and organizes names, ages, and drink preferences (and then organizes that data within certain data structures), then we can talk about matching algorithms.
I will also add here that if you do have structured data, Collaborative filtering (mentioned by Shridhar) is a great starting place.
Collaborative filtering best suits your needs.
In the newer, narrower sense, collaborative filtering is a method of
making automatic predictions (filtering) about the interests of a user
by collecting preferences or taste information from many users
(collaborating). The underlying assumption of the collaborative
filtering approach is that if a person A has the same opinion as a
person B on an issue, A is more likely to have B's opinion on a
different issue than that of a randomly chosen person. For example, a
collaborative filtering recommendation system for television tastes
could make predictions about which television show a user should like
given a partial list of that user's tastes (likes or dislikes).[3]
Note that these predictions are specific to the user, but use
information gleaned from many users. This differs from the simpler
approach of giving an average (non-specific) score for each item of
interest, for example based on its number of votes.

How to implement personalized feed ranking?

I have an app that aggregates various sports content (news articles, videos, discussions from users, tweets) and I'm currently working on having it so that it'll display relevant content to the users. Each post has a like button so I'm using that to determine what's popular. I'm using the reddit algorithm to have it sorted on popularity but also factor in time. However, my problem is that I want to make it more personalized for each user. Each user should see more content based on what they like. I have several factors I'm measuring:
- How many of each content they watch/click on? Ex: 60% videos and 40% articles
- What teams/players they like? If a news is about a team they like, it should be weighed more heavily
- What sport they like more? Users can follow several sports
What I'm currently doing:
For each of the factors listed above, I'll increase the popularity score by X of an article. Ex: user likes videos 70% than other content. I'll increase the score of videos by 70%.
I'm looking to see if there's better ways to do this? I've been told machine learning would be a good way but I wanted to see if there are any alternatives out there.
It sounds like what your doing is a great place to start with personalizing your users feeds.
Ranking based on popularity metrics (likes, comments, etc), recency, and in you case content type is the basis of the EdgeRank algorithm that Facebook used to use.
There are a lot of metrics that you can apply to try and boost engagement. Something
user liked post from team x, y times, so boost activity in feed by log(x) if post if is from y, boost activity if it’s newer, boost activity if it’s popular, etc… You can start to see that these EdgeRank algorithms can get a bit unwieldy rather quickly the more metrics you track. Also all the hyper-parameters that you set tend to be fixed for each user, which won’t end up with the ideal ranking algorithm for every user. Which is where machine learning techniques can come into play.
The main class of algorithms that deal with this sort of thing are often called Learning to Rank, and can be on a high level generalized into 3 categories. Collaborative filtering techniques, content based techniques, and hybrid techniques (blend of the first two)
In you case with a feed that most likely gets updated fairly frequently with new items, I would take a look at content based methods. Typically these algorithms are optimized around engagement metrics such as likelihood that the user is going to click, view, comment, or like an activity within their feed.
A little bit of self-promotion: I wrote a couple blog posts that cover some of this that you may find interesting.
https://getstream.io/blog/instagram-discovery-engine-tutorial/
https://getstream.io/blog/beyond-edgerank-personalized-news-feeds/
This can be a lot a lot to take on, so you could also take a look at using a 3rd party service like Stream (disclaimer, I do work there) who helps developers build scalable, personalized feeds.

Beyond item-to-item recommendations

Simple item-to-item recommendation systems are well-known and frequently implemented. An example is the Slope One algorithm. This is fine if the user hasn't rated many items yet, but once they have, I want to offer more finely-grained recommendations. Let's take a music recommendation system as an example, since they are quite popular. If a user is viewing a piece by Mozart, a suggestion for another Mozart piece or Beethoven might be given. But if the user has made many ratings on classical music, we might be able to make a correlation between the items and see that the user dislikes vocals or certain instruments. I'm assuming this would be a two-part process, first part is to find correlations between each users' ratings, the second would be to build the recommendation matrix from these extra data. So the question is, are they any open-source implementations or papers that can be used for each of these steps?
Taste may have something useful. It's moved to the Mahout project:
http://taste.sourceforge.net/
In general, the idea is that given a user's past preferences, you want to predict what they'll select next and recommend it. You build a machine-learning model in which the inputs are what a user has picked in the past and the attributes of each pick. The output is the item(s) they'll pick. You create training data by holding back some of their choices, and using their history to predict the data you held back.
Lots of different machine learning models you can use. Decision trees are common.
One answer is that any recommender system ought to have some of the properties you describe. Initially, recommendations aren't so good and are all over the place. As it learns tastes, the recommendations will come from the area the user likes.
But, the collaborative filtering process you describe is fundamentally not trying to solve the problem you are trying to solve. It is based on user ratings, and two songs aren't rated similarly because they are similar songs -- they're rated similarly just because similar people like them.
What you really need is to define your notion of song-song similarity. Is it based on how the song sounds? the composer? Because it sounds like the notion is not based on ratings, actually. That is 80% of the problem you are trying to solve.
I think the question you are really answering is, what items are most similar to a given item? Given your item similarity, that's an easier problem than recommendation.
Mahout can help with all of these things, except song-song similarity based on its audio -- or at least provide a start and framework for your solution.
There are two techniques that I can think of:
Train a feed-forward artificial neural net using Backpropagation or one of it's successors (e.g. Resilient Propagation).
Use version space learning. This starts with the most general and the most specific hypotheses about what the user likes and narrows them down when new examples are integrated. You can use a hierarchy of terms to describe concepts.
Common characteristics of these methods are:
You need a different function for
each user. This pretty much rules
out efficient database queries when
searching for recommendations.
The function can be updated on the fly
when the user votes for an item.
The dimensions along which you classify
the input data (e.g. has vocals, beats
per minute, musical scales,
whatever) are very critical to the
quality of the classification.
Please note that these suggestions come from university courses in knowledge based systems and artificial neural nets, not from practical experience.

How the computer knows "Recommended for You"?

Recently, I found several web site have something like : "Recommended for You", for example youtube, or facebook, the web site can study my using behavior, and recommend some content for me... ...I would like to know how they analysis this information? Is there any Algorithm to do so? Thank you.
Amazon and Netflix (among others) use a technique called Collaborative filtering to suggest things you might like based on the likes/dislikes of others who have made purchases and selections similar to yours.
Is there any Algorithm to do so?
Yes
Yes. One fairly common one is to look at things you've selected in the past, find other people who've made those selections, then find the other selections most common among those other people, and guess that you're likely to be interested in those as well.
Yup there are lots of algorithms. Things such as k-nearest neighbor: http://en.wikipedia.org/wiki/K-nearest_neighbor_algorithm.
Here is a pretty good book on the subject that covers making these sorts of systems along with others: http://www.amazon.com/gp/product/0596529325?ie=UTF8&tag=ianburriscom-20&linkCode=as2&camp=1789&creative=9325&creativeASIN=0596529325.
It's generally done by matching you with other users who have similar usage history / profile and then recommending other things that they've purhased/watched/whatever.
Searching for "recommendation algorithm" yields lots of papers. Most algorithms incorporate "machine learning" algorithms to determine groups of things (comedy movies, books on gardening, orchestral music, etc.). Your matching with those groups yields recommendations. Some companies use humans to classify things, too.
Such an algorithm is going to vary wildly from company to company. In many cases, it analyzes some combination of your search history, purchase history, physical location, and other factors. It probably will also compare purchases/searches amongst other people to find what those people have purchased/searched for, and recommend some of those products to you.
There are probably hundreds of these algorithms out there, but I doubt you can use any of them (that are actually good). Probably you are better off figuring it out yourself.
If you can categorize your contents (i.e. by tagging or content analysis), you can also categorize your users and their preferences.
For example: you have a video portal with 5 million videos .. 1 mio of them are tagged mostly red. If 80% of all videos watched by a user (who is defined by an IP, a persistent user account, ...) are tagged mostly red, you might want to recommend even more red videos to him. You might want to refine your recommendations by looking at his further actions: does he like your recommendations -- if so, why not give him even more, if not, try the second-best guess, maybe he's not looking for color, but for the background music ...
There's no absolute algorithm to do it, but all implementations will go into a similar direction. It's always basing on observing users, which scares me from time to time :-)
There's whole lot of algorithms tackling the issue: Wiki article. It's a Machine Learning domain problem. Computer's can be learned using two main techniques: classification and clustering. They require some datasets as input. If the dataset is informative (really holds some useful patterns) than those ML techniques can dig most of it.
Clustering could be best to use for this kind of problem. It's main usage is to find similarities among points in provided dataset. If the points are, e.g. your search history, they can be grouped together to form certain clusters. If Your search history closely relates to another, a hint can be given - picking links that are most similar to Your's.
The same comes with book recommendations - it's obvious what dataset they use: "Other people who bought this product also bought Product A, Product B,...". The key here is to match your profile to other's and use the most similar to recommend.
The computer retrieves information from the human brain with complex memory scan process, sorts it accordingly and outputs results based on what you have experienced in your life so far.

How does the Amazon Recommendation feature work?

What technology goes in behind the screens of Amazon recommendation technology? I believe that Amazon recommendation is currently the best in the market, but how do they provide us with such relevant recommendations?
Recently, we have been involved with similar recommendation kind of project, but would surely like to know about the in and outs of the Amazon recommendation technology from a technical standpoint.
Any inputs would be highly appreciated.
Update:
This patent explains how personalized recommendations are done but it is not very technical, and so it would be really nice if some insights could be provided.
From the comments of Dave, Affinity Analysis forms the basis for such kind of Recommendation Engines. Also here are some good reads on the Topic
Demystifying Market Basket Analysis
Market Basket Analysis
Affinity Analysis
Suggested Reading:
Data Mining: Concepts and Technique
It is both an art and a science. Typical fields of study revolve around market basket analysis (also called affinity analysis) which is a subset of the field of data mining. Typical components in such a system include identification of primary driver items and the identification of affinity items (accessory upsell, cross sell).
Keep in mind the data sources they have to mine...
Purchased shopping carts = real money from real people spent on real items = powerful data and a lot of it.
Items added to carts but abandoned.
Pricing experiments online (A/B testing, etc.) where they offer the same products at different prices and see the results
Packaging experiments (A/B testing, etc.) where they offer different products in different "bundles" or discount various pairings of items
Wishlists - what's on them specifically for you - and in aggregate it can be treated similarly to another stream of basket analysis data
Referral sites (identification of where you came in from can hint other items of interest)
Dwell times (how long before you click back and pick a different item)
Ratings by you or those in your social network/buying circles - if you rate things you like you get more of what you like and if you confirm with the "i already own it" button they create a very complete profile of you
Demographic information (your shipping address, etc.) - they know what is popular in your general area for your kids, yourself, your spouse, etc.
user segmentation = did you buy 3 books in separate months for a toddler? likely have a kid or more.. etc.
Direct marketing click through data - did you get an email from them and click through? They know which email it was and what you clicked through on and whether you bought it as a result.
Click paths in session - what did you view regardless of whether it went in your cart
Number of times viewed an item before final purchase
If you're dealing with a brick and mortar store they might have your physical purchase history to go off of as well (i.e. toys r us or something that is online and also a physical store)
etc. etc. etc.
Luckily people behave similarly in aggregate so the more they know about the buying population at large the better they know what will and won't sell and with every transaction and every rating/wishlist add/browse they know how to more personally tailor recommendations. Keep in mind this is likely only a small sample of the full set of influences of what ends up in recommendations, etc.
Now I have no inside knowledge of how Amazon does business (never worked there) and all I'm doing is talking about classical approaches to the problem of online commerce - I used to be the PM who worked on data mining and analytics for the Microsoft product called Commerce Server. We shipped in Commerce Server the tools that allowed people to build sites with similar capabilities.... but the bigger the sales volume the better the data the better the model - and Amazon is BIG. I can only imagine how fun it is to play with models with that much data in a commerce driven site. Now many of those algorithms (like the predictor that started out in commerce server) have moved on to live directly within Microsoft SQL.
The four big take-a-ways you should have are:
Amazon (or any retailer) is looking at aggregate data for tons of transactions and tons of people... this allows them to even recommend pretty well for anonymous users on their site.
Amazon (or any sophisticated retailer) is keeping track of behavior and purchases of anyone that is logged in and using that to further refine on top of the mass aggregate data.
Often there is a means of over riding the accumulated data and taking "editorial" control of suggestions for product managers of specific lines (like some person who owns the 'digital cameras' vertical or the 'romance novels' vertical or similar) where they truly are experts
There are often promotional deals (i.e. sony or panasonic or nikon or canon or sprint or verizon pays additional money to the retailer, or gives a better discount at larger quantities or other things in those lines) that will cause certain "suggestions" to rise to the top more often than others - there is always some reasonable business logic and business reason behind this targeted at making more on each transaction or reducing wholesale costs, etc.
In terms of actual implementation? Just about all large online systems boil down to some set of pipelines (or a filter pattern implementation or a workflow, etc. you call it what you will) that allow for a context to be evaluated by a series of modules that apply some form of business logic.
Typically a different pipeline would be associated with each separate task on the page - you might have one that does recommended "packages/upsells" (i.e. buy this with the item you're looking at) and one that does "alternatives" (i.e. buy this instead of the thing you're looking at) and another that pulls items most closely related from your wish list (by product category or similar).
The results of these pipelines are able to be placed on various parts of the page (above the scroll bar, below the scroll, on the left, on the right, different fonts, different size images, etc.) and tested to see which perform best. Since you're using nice easy to plug and play modules that define the business logic for these pipelines you end up with the moral equivalent of lego blocks that make it easy to pick and choose from the business logic you want applied when you build another pipeline which allows faster innovation, more experimentation, and in the end higher profits.
Did that help at all? Hope that give you a little bit of insight how this works in general for just about any ecommerce site - not just Amazon. Amazon (from talking to friends that have worked there) is very data driven and continually measures the effectiveness of it's user experience and the pricing, promotion, packaging, etc. - they are a very sophisticated retailer online and are likely at the leading edge of a lot of the algorithms they use to optimize profit - and those are likely proprietary secrets (you know like the formula to KFC's secret spices) and guaarded as such.
This isn't directly related to Amazon's recommendation system, but it might be helpful to study the methods used by people who competed in the Netflix Prize, a contest to develop a better recommendation system using Netflix user data. A lot of good information exists in their community about data mining techniques in general.
The team that won used a blend of the recommendations generated by a lot of different models/techniques. I know that some of the main methods used were principal component analysis, nearest neighbor methods, and neural networks. Here are some papers by the winning team:
R. Bell, Y. Koren, C. Volinsky, "The BellKor 2008 Solution to the Netflix Prize", (2008).
A. Töscher, M. Jahrer, “The BigChaos Solution to the Netflix Prize 2008", (2008).
A. Töscher, M. Jahrer, R. Legenstein, "Improved Neighborhood-Based Algorithms for Large-Scale Recommender Systems", SIGKDD Workshop on Large-Scale Recommender Systems and the Netflix Prize Competition (KDD’08) , ACM Press (2008).
Y. Koren, "The BellKor Solution to the Netflix Grand Prize", (2009).
A. Töscher, M. Jahrer, R. Bell, "The BigChaos Solution to the Netflix Grand Prize", (2009).
M. Piotte, M. Chabbert, "The Pragmatic Theory solution to the Netflix Grand Prize", (2009).
The 2008 papers are from the first year's Progress Prize. I recommend reading the earlier ones first because the later ones build upon the previous work.
I bumped on this paper today:
Amazon.com Recommendations: Item-to-Item Collaborative Filtering
Maybe it provides additional information.
(Disclamer: I used to work at Amazon, though I didn't work on the recommendations team.)
ewernli's answer should be the correct one -- the paper links to Amazon's original recommendation system, and from what I can tell (both from personal experience as an Amazon shopper and having worked on similar systems at other companies), very little has changed: at its core, Amazon's recommendation feature is still very heavily based on item-to-item collaborative filtering.
Just look at what form the recommendations take: on my front page, they're all either of the form "You viewed X...Customers who also viewed this also viewed...", or else a melange of items similar to things I've bought or viewed before. If I specifically go to my "Recommended for You" page, every item describes why it's recommended for me: "Recommended because you purchased...", "Recommended because you added X to your wishlist...", etc. This is a classic sign of item-to-item collaborative filtering.
So how does item-to-item collaborative filtering work? Basically, for each item, you build a "neighborhood" of related items (e.g., by looking at what items people have viewed together or what items people have bought together -- to determine similarity, you can use metrics like the Jaccard index; correlation is another possibility, though I suspect Amazon doesn't use ratings data very heavily). Then, whenever I view an item X or make a purchase Y, Amazon suggests me things in the same neighborhood as X or Y.
Some other approaches that Amazon could potentially use, but likely doesn't, are described here: http://blog.echen.me/2011/02/15/an-overview-of-item-to-item-collaborative-filtering-with-amazons-recommendation-system/
A lot of what Dave describes is almost certainly not done at Amazon. (Ratings by those in my social network? Nope, Amazon doesn't have any of my social data. This would be a massive privacy issue in any case, so it'd be tricky for Amazon to do even if they had that data: people don't want their friends to know what books or movies they're buying. Demographic information? Nope, nothing in the recommendations suggests they're looking at this. [Unlike Netflix, who does surface what other people in my area are watching.])
I don't have any knowledge of Amazon's algorithm specifically, but one component of such an algorithm would probably involve tracking groups of items frequently ordered together, and then using that data to recommend other items in the group when a customer purchases some subset of the group.
Another possibility would be to track the frequency of item B being ordered within N days after ordering item A, which could suggest a correlation.
As far I know, it's use Case-Based Reasoning as an engine for it.
You can see in this sources: here, here and here.
There are many sources in google searching for amazon and case-based reasoning.
If you want a hands-on tutorial (using open-source R) then you could do worse than going through this:
https://gist.github.com/yoshiki146/31d4a46c3d8e906c3cd24f425568d34e
It is a run-time optimised version of another piece of work:
http://www.salemmarafi.com/code/collaborative-filtering-r/
However, the variation of the code on the first link runs MUCH faster so I recommend using that (I found the only slow part of yoshiki146's code is the final routine which generates the recommendation at user level - it took about an hour with my data on my machine).
I adapted this code to work as a recommendation engine for the retailer I work for.
The algorithm used is - as others have said above - collaborative filtering. This method of CF calculates a cosine similarity matrix and then sorts by that similarity to find the 'nearest neighbour' for each element (music band in the example given, retail product in my application).
The resulting table can recommend a band/product based on another chosen band/product.
The next section of the code goes a step further with USER (or customer) based collaborative filtering.
The output of this is a large table with the top 100 bands/products recommended for a given user/customer
Someone did a presentation at our University on something similar last week, and referenced the Amazon recommendation system. I believe that it uses a form of K-Means Clustering to cluster people into their different buying habits. Hope this helps :)
Check this out too: Link and as HTML.

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