The world we live in is awashed with data that comes pouring in from everywhere around us. On it own, this data is just noise and confusion. To make sense of data, to find the meaning in it, we need a powerful branch of science: statistics. Believe me, there's nothing boring about statistics especially not today, when we can make the data sing. With statistics we can really make sense of the world. Are statistics, the data diluge as it's been called, leading us to a greater understanding of the life on Earth and the world beyond? Thanks to incredible power of today's computers it may fundamentally transform the process of scientific discovery. I kid you not, statistics is now the sexiest subject around. Did you know that there's is one million boats in Sweden? That's one boat per nine people. It's the highest number of boats per person in Europe. Being statistician, you don't like telling your profession at dinner parties, but really, statisticians shouldn't be shy because they always want to understand what's going on. Stastistics gives us a persperctive of the world we live in that we can't get in any other way. Statistics tells us whether the things we think and believe are actually true. Statistics are far more useful than we usually like to admit. In the last recession, there was this famous call into Talk Radio Station. The man complained: "in times like this, when unemployment rates are up to 13%, and income has fallen by 5%, and suicide rates are climbing, I get so angry that the government is wasting money on things like correctional statistics." I'm not oficially a statistician, strictly speaking my field is global health. But I got really obsessed with stats, when I realised how many people in Sweden don't know anything about the rest of the world. I started in our Medical University in Karolinksa Institute, an ungraduate course called Global Health. These students coming to us have actually the highest grades you can get in theSwedish college system. So I thought maybe they know everything I'm going to teach them. So I did a pre-test when they came. One of the questions, from which I learnt a lot, was: Which country has the highest child mortality of these five pairs? I won't put you at test here, but it's Turkey which is higher there, Poland, Russia, Pakistan and South Africa. And these were the results of the Swedish students. 1.8 answers right out of 5 possible, that means that there was a place for a professor in International Health and for my course. But one late night when I was compiling my report I really realise my discovery. I have shown that Swedish top students know statistically significantly less about the world than the chimpanzees. Beacuse the chimpanzee would score half right. If I gave them two bananas with Sri Lanka and Turkey they would be right half of the cases. But the students are not there. I did also an unethical study of the professors of the Karolinska Institute that hands out the Nobel Prize in Medicine, and they aren't on par with the chimpanzee. Today, there's more information accesible than ever before, and I work with my team at the Gapminder Foundation using new tools that help everyone make sense of the changing world. We draw on the masses of data that are now free available from international institutions like the UN and the World Bank. It's become my mission to share my insights from this data with anyone who listen, and to reveal how statistics is nothing to be frightened of. I'm going to provide you a view of the global health situation across mankind, and I'm going to do that in a hopefully enjoyable way. So relax. We did this software which displays it like this, every bubble here is a country, this is China, this is India. The size of the bubble is the population. And I'm going to stage a race here between this sort of yellow Ford here, and the red Toyota down there, and the brownish Volvo. The Toyota has a very bad start down here, and United States' Ford is going off road there, and the Volvo is doing quite fine, this is the war, they Toyota got off crack, now Toyota is coming on the healthier side of Sweden. That's the point when I sold the Volvo and bought the Toyota. This is the Great Leap Forward when China fell down, it was central planning by Mao Tse Tung, China recovered and said "never more stupid central planning", but they went up here. No, there was one more inequity, look there! United States! Oh, they broke my frame! Washington D.C. is so rich over there, but it's not as healthy as Kerala, India. It's quite interesting, isn't it? Welcome to the USA, world leaders in big cars and free data. There are many here who share my vision of making public data accesible and useful for everyone. The city of San Francisco is in the lead, opening up it's data on everything. Even the Police Dept. is releasing all it's crime reports. This official crime data has been turned into a wonderful inteactive map by two of the cities computer whizzes. It's community statistics in action. Crimespotting is a map of crime reports from the San Francisco Police Dept. showing dots on maps for citizens to be able to see patterns of crime in their neighbourhoods in San Francisco. The map is not just about individual crimes but about broader patterns that show you where crime is clustered around the city, which have high crime, which areas have relatively low crime. We're here at top of Jones Street, on uphill, quite a nice neighbourhood what the crime maps show us is the relationship between typography and crime. The higher up the hill, the less crime there is. We crossed over the border into the flats. Essentially, as soon as you get into the kind of lower line areas of Jones street, the crime just skyrockets. So we're in the uptown Tenderloin District, it's one of the oldest and most dangerous neighbourhoods in San Francisco. This is where you go to buy drugs, right around here. You see lots of aggreviated assault, lots of thefts. Basically, the huge part of the crime of the city happens right in these four or six block areas. If you've been hearing police sirens in your neighbourhood, you can use the map to find out why. If you are out at night in an unfamiliar part of town you can check the map for streets to avoid. If a neighbour gets burglared, you can see, is it the one off or has there been a spike in local crime? If you commute through a neighbourhood and you're worried about its safety the fact that we have the ability to turn off all the night time and middle-of-the-day crimes and show you just the things that are happening during your commute, is a statistical operation but I think to the people that are interacting with the thing it feels very much more like they just are sort of browsing a website or shopping on Amazon. They're looking at data, and they don't realise that they're doing statistics. What's most exciting for me is that public statistics is making citizens more powerful and the authorities more accountable. We have community meetings that the police attend and what citizens are now doing, they're bringing printouts of the maps to show where crimes are taking place, and they're demanding services from the police department, which is now having to change how they please, how they provide policing services, because the data is showing what is working and what is not. People in San Francisco are also using public data to map social inequalities, and see how to improve society and the possibilities are endless. Our dream would be that the government announced that this data project would really focus on live information on stuff that was being reported and pushed out into the world as it was happening. Trash pickup, traffic accidents, buses, and through the kind of the stats gathering power on the internet it's posible to really see the workings of the city displayed as a unified interface. That's where we are heading, towards a world of free data with all the statistical insights that come from it accesible to everyone, empowering us as citizens and letting hold our rulers to account. It's a long way from where statistics began. Statistics are essential to monitor our government in our societies. But, it was our rulers out there who started the collection of statistics in first place in order to monitor us. In fact the word statistics comes from state. Modern statistics began two centuries ago. Once it got going it spread and never stopped. And guess who was first. The Chinese have Confucious, the Italians have Da Vinci, and the British have Shakespeare, and we have the Tabellverket the first ever systematic collection of statistics. Since the year 1749 we have collected data on every birth, marriage and death and we are proud of it. The Tabellverket recorded information from every parish in Sweden. It was a huge quantity of data and it was the first time any goverment could get any accurate picture of its people. Sweden had been the greatest military power in Northern Europe but by 1749 our star was really fading and other countries were growing stronger. At least though, we were a large power, thought to have 20 million people enough to rival Britain and France. But we were in for a nasty surprise. The first analysis of Tabellverket revealed that Sweden only had 2 million inhabitants. Sweden was not only a power in decline, it also had a very small popoulation. The government was horrified by this finding. What if the enemy found out? But the Tabellverket also showed that many women die in childbirth. And many children died young, and government took action to improve the health of the people. That was the beginning of modern Sweden. It took more than 50 years before the Austrians, Belgiums, Danes, Dutch, Germans, Italians and finally the British caught up with Sweden in collecting and using statistics. It was called political arithmethic, and it was a lovely phrase as use for statistics. Governments could have much more control and understanding of the society how it's working, how it's developing, and essentially, so they could control it better. It wasn't just governments who woke up to the power of statistics. Right across Europe, 19th century society went mad for facts. And despite its late start, Britain with its Royal Statistical Society in London was soon a statisticians' nirvana. I love looking at old copies of the Royal Statistical Society, because is full of this stuff. There's a wonderful paper from the 1840s which shows a map of England and the rates of bastardy of each county so you can identify very quickly the areas with high areas of bastardy. Being in East Anglia makes me slightly laugh that Norfolk was on top of the bastardy league in the 1840s. One of the founders of the Royal Statistical Society was the great victorian mathematician and inventor Charles Babbage. In 1842 he read the latest poem by a equally great victorian Alfred Tennyson. "Vision of Sin" contained the lines: "Fill the cup and fill the can, Have a rouse before the morn. Every moment dies a man, Every moment one is born." So keen statistician was Babbage that he could not contain himself. He dashed a letter to Tennyson explaining that because of population growth the line should read: "Every moment dies a man, And 11/16 is born." "I may add that the exact figure is 1.167 but something must be conceded to the laws of metre." In the 19th century scholars all over Europe did an amazing work in measuring the societies. They hovered up data in almost everything but numbers alone don't tell you anything you have to analyse them, and that's what makes statistics. When the first statisticians began to get to grips with analysing their data they seized upon the average, and they took the average of everything. What's so great about an average is that you can take a whole mass of data and reduce it to a single number. Though each of us is unique, our collective lives produce averages that characterise whole populations. I look to my local newspaper one week and saw that a pensioner had accidently put a foot on the accelerator and crashed her friend against the wall. Devastating, hideous, horrible thing to happen. And there was a second one about a young man who didn't have a driving licence who was driving a car under the influence of drugs and alcohol and crashed into a pedestrian and killed him. What is remarkable, absolutely remarkable, if you look at the number of people who die each year in traffic accidents, it's nearly a constant. What? All these individual events, somehow when you sum them all up it's the same number every year, and every year two and a half times as many men die in traffic accidents as women, and it's a constant. An every year the rate in Belgium is double the rate in England, there are these remarkable regularities so that these individual particular events sum up into a social phenomenon. (Lecture) Let's see what Sweden has done we used to boast of fast social progress. (Narration) In my lectures, to tell stories about the changing world I use averages for entire countries, whether the average for income, child mortality, family size or carbon output. (Lecture) OK, I give you Singapore, the year I was born. Singapore had twice the child mortality of Sweden. The most tropical country in the world. A marshland on the Equator. And here we go. It took a little time for them to get independence but they started to grow their economy, and they made the social investments, they got away malaria, they got a magnificient health system that beats both UkKs and Sweden's. We thought it would never happened but they would win over Sweden! But useful as averages are they don't tell you the whole story. On average, Swedish people have slightly less than two legs. That is because a few people have one leg or no legs, and no one has three legs so almost everybody in Sweden has more than the average number of legs. The variation in data is just as important as the average. But how do you get the handle on variation? For this you transform numbers into shapes. Let's llok again at the number of adult women in Sweden for different heights. Plotting the data as a shape shows us how much their heights vary from the average and how wide that variation is. The shape a set of data makes is called its distribution. (Lecture) This is the income distribution of China 1970 This is the income distribution of the United States 1970. Almost no overlap. And what has happened? China is growing. It's not so equal any longer. And it's appearing here, overlooking the United States almost like a ghost, isn't it? It's scary! That statistician who first explored distribution discovered one shape that turned up again and again the victorian scholar Francis Goldtone was so fascinated he built a machine that could reproduce it and he found it fitted so many different sets of measurements that he named it the Normal Distribution. Whether it was people's arm spans, land capacity or even their exam results the Normal Distribution shape recurred time and time again. And the statisticians soon found many other regular shapes each produced by a certain kind of natural or social processes. And every statistician has their favourite. The Poisson distribution, I think it's my favourite, it's absolute crack. The Poisson shape, describes how likely it is that out-of-the-ordinary things will happen. Imagine a London bus stop that we know that on average will get three buses an hour. We won't always get three buses of course. Amazingly the Poisson shape will show us the probability that in any given hour will get 4, 5 or 6 buses or no buses at all. The exact shape changes with the average but whether it is how many people will win the lottery jackpot each week or how many people will phone a call centre each minute the Poisson shape will give the probabilities. The wonderful example where this does apply is in the late 19th century was to count each year the number of Prussian officers cavalry officers that had be kicked to death by their horses Some year there were none, some years one, some years two,... up to seven. One particularly bad year. But with this distribution, how many years they go, one, two three, four, Prussian cavalry officers kicked to death by their horses beautifully obbey the Poisson distribution. So statisticians use shapes so we wield the patterns in the data but we also use images of all kinds to communicate statistics to a wider public because if the story in the numbers is told by a beautiful and clever image then everyone understands. Of the pioneers of statiscal graphics, my favourite is Florence Nightingale. There are not many people who realise that actually she was known as a passionate statistician and not just the Lady of the Lamp. She said that to understand God's thoughts we must study statistics for these are the measure of His purpose. Statistics must reserve a religious studio moral imperative. When Florence was nine years old, she started collecting data. Her data was different fruits and vegetables she found. Put them into different tables, trying to organise them in some standard form, so we have one of the Nightgale's first statistical tables at the age of nine. In the mid-1850s, Florence Nightingale went to Crimea to care for British casualties at war. She was horrified by what she discovered. For all the soldiers being blown to bits on the battlefield there were many many more soldiers dying from diseases caught in the army's filthy hospitals. So Florence Nightingale bagan counting the dead. For two years she recorded mortality data in meticulous detail. When the war was over, she persuaded the government to set up a Royal Comission of Enquiry. And gathered her data in a devastating report. What has amended her place in the statistically history books is the graphics she used. And one in particular, the Polar Area Graph. For each month of the war, a huge blue wedge represented the soldiers who had died of preventable diseases. The much smaller red wedges were deaths from wounds, and the black wedges deaths from accidents and other causes. Nightingale graphics were so clear, they were impossible to ignore. The usual thing around Florence Nightingale's time was just to produce tables and tables of figures. Absolutely tedious stuff. Unless you are a dedicated statistician, it's quite difficult to spot the patterns naturally. But visualisations tell a story. They tell a story immediately. The use of colour, the use of shape, can really tell a powerful story. And these days, we can make things move as well. Florence Nightingale would've loved to play with it, she would've produced wonderful animations, I'm absolutely certain about it. Today, a hundred and fifty years on, Nightingale's graphics are rightly regarded as a classic. They led to a revolution in nursing and health care, in hygiene in hospitals worldwide. We've saved innumerable lives. Statistical graphics has become an art of its very own. Led by designers who are passionate about visualising data. This is the Billion Pound O Gram. This image arouse out of the frustration with the reporting of billion-pounds amounts in the media. 500 trillion pounds for this war, 50 million pounds for this hospital, this does not make sense, these figures are too enormous to get your mind around. So I squailed to this data from various news sources and created this diagram so the squares here are scaled according the the billion-pound amounts. When you see numbers visualised like this, you start to have a different kind of relationship with them. You can see patterns, see the scale of them. Here, this little square, 37 billion, this was the predicted cost of the Iraq war in 2003. As you can see it has grown exponentially over the last few years to the total cost of about 2,500 billion. It's funny because when you visualise statistics like this, you undestand them. And when you understand them, you can put things into perspective. Visualisation is right at the heart of my own work too. I teach Global Health. I know that having the data is not enough, I have to show it in ways people both enjoy and undestand. Now I'm going to try something I've never done before. Animating the data in real space. With a bit of technical assistance from the crew. So here we go! First an axis for health, life expectancy from 25 years to 75 years. Down here an axis for wealth, income per person, $400, $4,000 and $40,000. So down here is poor and sick. And up here is rich and healthy. Now I'm going to show you the world 200 years ago, in 1810. Here come all the countries: Europe brown, Asia red, Middle East green, Africa South-of-Sahara blue, and America is yellow. And the size of the country bubble shows the size of the population. And in 1810 it was pretty crowded down there, isn't it? All countries were sick and poor, life expectancy would be below 40 in all countries. Only the UK and the Netherlands were slightly better off, but not much. And now, I'll start the world! The Industrial Revolution makes countries in Europe and elsewhere move away from the rest. But the colonised countries in Asia and Africa are stuck down there. Eventually the Western countries get healthier and healthier. Now we slow down to see the impact of the First World War and the Spanish Flu Epidemy. What a catastrophe! Now I'll speed up through the 1920s and 1930s and spite of the Great Depression, Western countries fueled on towards greater wealth and health. Japan and some others try to follow but most countries stay down here. After the tragedies of the Second World War we stop a bit to look at the world in 1948. 1948 was a great year, the war was over, Sweden topped the medal table at the Winter Olympics, and I was born, but the differences between the countries of the world was wider than ever. United States was in the front, Japan was catching up, Brasil was way behind, Iran was getting a little richer from oil, but still had short lives. The Asian giants, China, India, Pakistan, Bangladesh and Indonesia, they were still poor and sit down here. But look what is about to happen. In my lifetime, former colonies gained independence and finally they started to get healthier, and healthier, and healthier. And in the 1970s, countries in Asia and Latin America started to catch up with the Western countries. They became the emerging economies. Some in Africa follow, some in Africa are stuck in civil wars, and others are hit by HIV. And now we can see the world today, in the most up-to-date statistics. Most people today live in the middle, but here are huge differences at the same time between the best of countries and the worst of countries and there are also huge inequalities within countries. These bubbles show country averages, but I can split them. Take China, I can split it into provinces. There goes Shanghai, it has the same health and wealth as Italy today. And then there's the poor inland province of Guizhou. It's like Pakistan. And if I split it further, the rural parts are like Ghana in Africa. And yet, despite the enormous disparities today, we have seen 200 years of remarkable progress. That huge historical gap between the West and the rest is now closing. We have become an entirely new converging world. And I see a clear trend into the future, with aid, trade, green technology and peace. It's fully possible that everyone can make it to the healthy-wealthy corner. What you've just seen in the last few minutes is a story of 200 countries shown over 200 years and beyond. It involved plotting 120,000 numbers. Pretty neat, eh? With statistics we can start to see things as they really are. From tables of data, to averages, distributions and visualisations, statistics gives us a clear description of the world. But with statistics we can not only discover what is happening but also explore why, by using the powerful analytical method of correlation. Just looking at one thing at a time doesn't tell you very much. You have to look at the relationships between things. How they change. How they vary together. That's what correlation is about. That's how we start to understand the processes that are really going on in the world and in socierty. Most of us would recognise today that crime correlates to poverty, that infection correlates to poor sanitasion, and that knowledge of statistics correlates to being great at dancing. Correlations can be very tricky. I've got a joke about silly correlations. This was this American who was afraid of heart attack. He found out that the Japanese ate very little fat, and almost didn't drink wine, and have much less heart attacks than the American. But on the other hand, he found out that the French eat as much fat as the Americans and they drink much more wine, but they also have less heart attacks. so he concluded that what kills you is speaking English. The best example of a really ground-breaking correlation was the link that was established in the 1950s between smoking and lung cancer. Not long after the Second World War, a British doctor, Richard Doll, investigated lung cancer patients in twenty London hospitals, and he became certain that the only thing they had in common was smoking so certain that he stopped smoking himself. But other people weren't so sure. Lots of the discussion of early data linking smoking and lung cancer it can't be smoking, surely, that thing we've done all our lives, that can't be bad for you. Maybe it's genes, maybe people who are genetically predisposed to get lung cancer are also genetically predisposed to smoke. Maybe it's not the smoking, maybe it's air pollution, that smokers and somehow more exposed to air pollution than non-smokers. Maybe it's not smoking, maybe it's poverty. So now we have three possible explanations apart from chance. To verify his correlation did imply cause and effect Richard Doll created the biggest statistical study of smoking yet He began tracking the lives of 40,000 British doctors some of whom smoked, some of whom didn't. And gathered enough data to correlate the amount of doctors who smoked with their likelihood of getting cancer. Eventually, he did not only show a correlation between smoking and lung cancer but also a correlation between stopping smoking and reducing the risk. This was science at its best. What correlations do not replace is human thought. We could think about what it means. What a good scientist does if he comes up with a correlation is try as hard as he or she possibly can to disprove it to break it down, to get rid of it, to try to refute it, and if it withstands all those efforts at demolishing it, and it still standing out, then we might really have something here. However brilliants the scientists, data is still the oxygen of science. The good news is that the more we have, the more correlations we'll find, the more theories we'll test, and the more discoveries we are likely to make. And history shows how our total sum of information grows in huge leaps as we develop new technologies. The invention of the printing press kicked off the first data and information explosion If you piled up all the books that have been printed by the year 1700 they would make sixty stacks, each as high as Mount Everest. Then, starting in the 19th century, there came a second information revolution. With the telegraph, gramophone, camera, and later radio and TV. The total amount of information exploded. And by the 1950s the information available to us all had multiplied six thousend times. Then, thanks to the computer, and later the Internet, we went digital, and the amount of data we have now, is unimaginably vast. A single letter printed in a book is the equivalent to a byte of data. A single page equals a kilobyte or two. Five megabytes is enough for the complete works of Shakespeare. 10 gigabytes, that's a DVD movie. 2 terabytes is the tens of millions of photos added to Facebook everyday. 10 petabytes is the data recorded every second by the world's largest particle accelerator, so much only a tiny fraction is kept. 6 exabytes is what you'd have if you sequenced the genomes of every single person on Earth. But really, that's nothing. In 2009, the Internet added up to 600 exabytes, and in 2010, in just one year, that will double to more than one zettabyte. But in the real world, if we turned all this data into print it would make ninety stacks of books, each reaching from here all the way to the Sun. The data deluge is staggering. But with today's computers and statistics, I'm confident we can handle it. When it comes to all the data on the Internet, the powerhouse of statistical analysis is the Sillicon Valley giant Google. The average person over their lifetime is exposed to about a hundred million words of conversation. So if you multiply that by the six billion people on the planet that amount of words is equal to the amount of words that Google has available at any one instant of time. Google's computers hoover up and file away every document, web page and image they can find. Then they hunt for patterns and correlations in all this data doing statistics on a massive scale. And for me, Google has one project that is particularly exciting: statistical language translation. If you do want to provide access to all the web's information no matter what language is spoken. There's so much information on the Internet, you can not hope to tranlate it all by hand into every possible language, we figured we have to be able to do machine translation. In the past, programmers tried to teach their computers to see each language as a set of grammatical rules. Much like languages are taught at school. But this didn't work, because no set of rules could capture language in all its subtlety and ambiguity, Having eaten out lunch, the coach departed. That's obviously incorrect. Written like that, it would imply that the coach has eaten the lunch. It would be far better to say: Having eaten our lunch, we departed in the coach. Those rules are helpful, they are useful most of the time, but they don't turn out to be true all the time. And the insight of using statistical machine translation is saying: if we have all these exceptions anyways, maybe you can get by without having any rules, maybe we can treat everything as an exception, and that's essentially what we've done. What the computer is doing when it's learning how to translate is to learn correlations between words and between phrases so we feed the system very large amounts of data and the the system sees if a certain word or phrase correlates very often to the other language. Google's website currently offers translation between any of 57 different languages. It does this purely statistically,having correlated the huge collection of multilingual texts. The people who built he system don't need to know Chinese in order to build the Chinese system. They dont need to know Arabic. The expertise that is needed is basically knowledge of statistics, of computer science, of infrastructure, to build these very large computer systems we are building for doing that. I hooked up with Google from my office in Stockholm, to try the translator by myself. I will type some Swedish sentences. (Types in Swedish) (Reads on the screen) Sweden's finance minister has a ponytail and a gold ring in your ear. It's almost exactly correct, it's amazing. He comes from the conservative party, that's the kind of Sweden we have today. I will type one more sentence. In his same-sex parnertships has Stockholm's new bishop and his partners a three-year son. It's almost perfect, there's one important thing, it's "her". It's a lesbian partnership. OK, those kinds of words like "her" are one of the challenges in translation, to get those right. When it comes to bishops, one can excuse it. Right, I think that more often than not it would be probably a "his". I will write one more sentence. (Reads aloud in Swedish) When Sweden is taking part in Olympic gold, is not to win but to beat Norway. But they are very good in Winter Olympics, so we can't make it, but we are trying. Very good, very good. This is absolutely amazing, and I'm impressed that it picked up words like "same-sex partnerships" which are very due to the language. The translator is good, but if it succeeds, what will be next, that'll be remarkable. One of the exciting possibilities is combining the machine translation technology with the speech recognition technology. Both of these are statistically neutre. The machine translation relies on the statistics of mapping from one language to another, and similarly speech recognition relies on the statistics of mapping from a sound form to the words. When we put them together, now we have the capability of having instant conversations between two people who don't speak a common language. I can talk to you in my language, you hear me in your language, and you can answer back in real time, we can make that translation, we can bring people together and allow them to speak. The Internet is just one of many technologies created to gather massives amount of data. Scientists studying our Earth and our environment now use an incredible range of instruments to measure the processes of our planet. All around us our sensors are continously measuring temperature, water flow and ocean currents. High in orbit our satellite is busy imaging cloud formations, forest growth and snow cover. Scientists speak of instrumenting the Earth. And pointing up to the skies above, our powerful new telescopes are mapping the Universe. What's happening in astronomy, is tipically how profoundly this torrent of data is transforming science. Astronomers are now addressing many enduring misteries of the cosmos by applying statistical methods to all this new data. The galaxy is a very big place and it has billions of starts in it so to put toghether a coherent picture of the whole galaxy requires having enourmous amounts of data, and before you can do a large sky survey with sensitive digital detectors, that you can map many stars at once, it's very difficult to gather enough data of enough of the galaxy. In the past, large surveys of the night sky had to be done by exposing thousands of large photographic plates, but these surveys could take 25 years or more to complete. Then, in the 1990s, came digital astronomy, and a huge increase in both the amount and the accesibility of data. The Sloan Sky Survey is the world's biggest yet using a massive digital sensor mounted on the back of a custom built telescope in New Mexico. It's scanned the sky night after night for eight years building up a composite picture in unprecedented resolution. The Sloan's is some of the best deepest survey data we have in astronomy, both in our galaxy and galaxies away from ours. All the Sloan data is on the Internet and with it astronomers have identified millions of hidden unknown stars and galaxies. They also comb the database for statistical patterns which will prove, disprove or suggest new theories. So we have this idea that galaxies grow they become large galaxies like the one we live in, the Milky Way. Not all at once, not smoothly but by continously incorporating cannibalising smaller galaxies they dissolve them and become part of the bigger galaxy It's a startling idea and in the Sloan data there's the evidence to support it. Groups of starts that came from cannibalised galaxies stand out in the Sloan data statistically different from other stars. because they move at a different velocity. Each big spike of one of these distribution graphs means professor Rockossi has found a group of stars all travelling in a different way to the rest. They are the telltale patterns she's looking for. The evidence is accumulating that in fact this really is how galaxies grow or an important way of how galaxies grow this is important to understand how galaxies form not only ours but every galaxy. The more data there is the more discoveries can be made and the technology is getting better all the time. The next big survey telescope starts its work in 2015. It will leave Sloan in the dust. Sloan has taken 8 eight years to cover one quarter of the nightsky. The new telescope will scan the entire sky in even greater resolution every three days. The vast amounts of data we have today allows researchers in all sorts of fields to test their theories in a previously unimaginable scale but it may even change the fundamental way science is done. With the power of todays' computers applied to all this data the machines might be able to guide the researchers. There is a profoundly important, one of the most significant points in science certainly one of the most exciting the potential to transform not only how scientists do science but what science is possibly. What will power that transformation of how science is done is going to be computation. Many of the dynamics of the natual world like the interplay between the rainforest and the atmosphere are so complex, that we don't yet really understand. But now computers are generating tens of thousands of simulations of how these biological systems might work. Is like creating thousands of hypothetical parellel worlds. Each of these simulations is analysed with statistics to see if any are a good match of what is observed in each. The computers can now automatically generate, test and discard hypothesis with scarcely human insight. This new application statistics will become absolutely vital for the future of science. It's creating a new paradigm in the way we do science which is characterised as data-centric or data-driven rather than hypothesis- or experiment-driven. It's an exciting time in terms of science, computation and statistics. If all this sounds a bit abstract to you how about one final frontier? Could statistics make sense of your feelings? In California, (where else!), one computer scientist is harvesting the Internet to try to define the patterns of our innermost thoughts and emotions. This is the Madness Movement it represents a skyscrapper's view of the world. Each brightly coloured dot is an individual feeling expressed by someone out there in a blog or a tweet and when you click on the dot it explodes to reveal the underlying feeling of that person. This is what people say they're feeling today: better safe crappy well pretty special sorry alone Every minute WeFeelFine crosses the world's blogs takes all the sentences that start with the words "I feel" or "I'm feeling" and push them into a database. We collect all the feelings and we count the most common better bad good right guilty sick the same like shit sorry well We can take a look at any one feeling and analyse it. Right now a lot of people are feeling happy. We can take a look at these people, and break them down by age, gender or location. Since bloggers have public profiles, we have that information and we can ask questions like, "Are women happier than men?" or "Is England happier than the United States?" We find that as people get older, they get happier. For younger people, happiness associates with excitement whereas older people associate happiness more with peacefulness. We also find than women feel loved more often than men, but also more guilty. While men feel good more often than women, but also more alone. As people live more and more of their lives online they leave behind digital traces with which we can statistically analyse what it means to be human. Where does all this leave us? We generate unimaginable quantities of data About everything you can think of and we analyse it to reveal the patterns. Now not only experts but all of us can understand the stories in the numbers. Instead of being led astray by prejudice with statistics at our fingertips, our eyes can be open for a facts-based view of the world. More than ever before we can become authors of our own destiny. And that's pretty exciting isn't it? (Music)