Escaping the boundaries of human perspective is a fundamental task of science. Telescopes cross distance; microscopes, size; other tools detect sounds beyond hearing or light beyond sight.

Datasets spanning years and decades allow patterns to emerge on scales outside the days and weeks of customary attention. In astronomy, of course, where multi-decade records sparked the Age of Wonder, long-term datasets are now routine. Ditto geology, the discipline which made it possible to conceive deep time. But other fields, especially in the life sciences, are just catching up. In the 20th century, biologists, ecologists and epidemiologists launched many long-term studies, designed with an eye beyond their own time. More recently, researchers have mined records — from captains' logs to Google Books — that in retrospect contain useful data. The approaches embody some of science's great virtues: foresight, patience and cleverness. On the following pages, Wired Science presents some of its favorite long-term datasets. Above: Japanese Cherry Blossom Festivals In Japan, cherry blossom festivals are an ancient and wildly popular tradition, featuring days-long celebrations carefully timed to coincide with peak flowering. The festivals are so prominent in Japanese culture that their collective descriptions in diaries, literature and administrative records have been turned into a six-century-long record of blossoming dates and locations across the islands. Because the trees blossom at certain temperatures, scientists can infer historical weather information, and ultimately climate trends, from these dates. Few other historical climate records contain such fine-grained detail. Images: Above) Kazuhiko Teramoto/Flickr Below) Top row, the known dates of full cherry flowering from the 11th century to present. April 1 is the year's 91st day, and May 1 is the 122nd. Bottom row, estimated historical March temperatures as calculated from flowering dates. (Yasuyuki Aono & Yuko Omoto/Journal of Agricultural Meteorology)

Continuous Plankton Recorder Designed in 1931 by marine biologist Alister Hardy, the Continuous Plankton Recorder is a biopunk-named, nondescript-looking steel box containing two skeins of silk mesh. When it's dipped into the sea, plankton are trapped between them. Since sampling methods were formalized in 1948, nearly 300 ocean-crossing ships have carried CPRs from their bows. Sample by sample, over millions of miles, they've produced a global record of activity at the base of oceanic food chains. Images: Above) A Continuous Plankton Recorder unit hangs from prow of a ship. (Sandra Zicus/Australian Antarctic Division) Below) Decade-by-decade spatial distribution of plankton and small crustacean biomass for the northwestern European shelf. (Sophie Pitois & Clive Fox/ICES Journal of Marine Science)

Chillingham Cattle The wild cattle of Chillingham, England have been studied since 1860, when their original owner was encouraged in record-keeping by none other than Charles Darwin, a man uniquely positioned to appreciate long-term datasets. Since the 1950s, Chillingham cows calved during winter with increased frequency. This appears to be a function of climate change: Warmer springs result in earlier vegetation growth, which result in earlier mating. Unfortunately for calves, winter is a difficult time to be born. Images: Above) Chillingham cattle. Yellow Book/Flickr Below) Proportion of births occurring in each season per year over a 62-year period. (Burthe et al./Journal of Animal Ecology)

Florida Fishing Trip Photographs Fish stories are synonymous with tall tales, but photographs are another matter, and snapshots taken by charter boat operators in Key West, Florida provide year-by-year documentation of an ecosystem in transition. Overfishing and reef destruction almost eliminated large fish, then medium-sized fish, finally leaving only the small ones. Images: Above) Trophy fish caught on a Key West charter boat in 1957 (Loren McLenachan/Conservation Biology) Below) Top, fish caught in the early 1980s; middle, fish caught in 2007; and at bottom, species composition of displayed fish arranged in order from largest to smallest. (Loren McLenachan/Conservation Biology)

Isle Royale Wolves During an especially deep winter in 1949, two wolves from Ontario crossed a frozen Lake Superior, arriving at Michigan's Isle Royale. The island teemed with moose, and the pair stayed; nine years later, Purdue University wildlife ecologist Durward Allen started to study them. They've been monitored ever since in what may be the single longest-running study of any animal population. A trove of fantastically detailed information has been gathered about the wolves, such as the exact locations where they've killed 3,654 moose since 1958. In recent years, chemical analysis techniques have allowed Isle Royal researchers to quantify the flow of nutrients that represents, with each carcass ultimately feeding plants and animals over three square acres. From this perspective, wolves don't simply kill moose; they spread life across the island. Images: Above) Wolves and pup. (United States Department of Agriculture/Man and Biosphere Program) Below) Top left, a wolf-killed moose carcass; top right, the same carcass three days later. In the middle is a map of moose carcass density between 1958 and 1982; below, a map of changes in carcass density between that period and 1983-2006. (Bump et al./Ecology)

E. coli Long-Term Experimental Evolution Project Long-term studies of animals like the Chillingham cattle and Isle Royale's wolves can hint at evolutionary trends, but a deeper picture of evolution requires hundreds or thousands of generations. At Michigan State University, microbiologist Richard Lenski has tracked 12 once-identical Escherichia coli populations that were seeded in 1988 and have evolved independently ever since, a period of time spanning 50,000 generations. Lenski's E. coli strains are now distinct, each possessing unique adaptations and traits, and research on them has deepened scientific understanding of evolution's underlying principles — such as the very nature of evolvability itself. Images: Above) Flasks containing samples from Lenski's 12 original populations. (Brian Baer and Neerja Hajela/MSU/Wikimedia Commons) Below) Long-term trait frequencies in strains of Lenski's E. coli. (Lenski et al./Science)

Google Books Cultural evolution clearly happens, but it's difficult to study with the formal rigor of biological evolution. With a few exceptions, such as anthropological monographs of canoe design in Polynesia, the data's just too messy. But with the advent of digital archiving and analysis tools, anything that can be scanned and formatted as text is a potential source of cultural data; the 2010 Science publication of an investigation into the century-spanning, 500 billion word-deep database of Google Books hinted at what might be possible. Images: Above) Stewart Butterfield/Flickr Below) Name frequencies in English-language Google Books texts over the 20th century. (Michel et al./Science)

Framingham Heart Study In 1948, some 5,209 adult residents of Framingham, a blue-collar Massachusetts town, enrolled in what would become the longest-running epidemiological study ever. Nothing like it had been done; the participants would submit to medical checkups every year, eventually giving researchers a large-scale, long-term picture of human health. The study is now on its third generation; much of what's now considered bedrock conventional wisdom about heart disease and stroke — such as their links to cigarette smoking, high cholesterol and high blood pressure — were actually groundbreaking insights from Framingham. Images: Above) Walter Sullivan and Jane Klug, two of the Framingham Heart Study's founders and original participants, photographed in October 2010. (Framingham Heart Study) Below) Correlation of stroke mortality risk (y-axis) and blood pressure (x-axis) with age in men and women. (Lewington et al./Lancet)

20th Century Reanalysis Project Completed just this year, the 20th Century Reanalysis Project combines historical records from a hodgepodge of sources — the records of sea captains and explorers, doctors and old news accounts — into detailed weather maps, giving the late-19th and 20th centuries a modern level of meteorological coverage. Images: Above) Historic weather map for Jan. 28, 1922, the day the Knickerbocker Storm hit Washington, D.C. (NOAA Central Library Data Imaging Project) Below) Reconstructed meteorological conditions for that day. (J. Whitaker/NOAA Earth System Research Lab)

Ice Cores Ice cores — long, cylindrical sections of ice removed from polar ice caps and glaciers — are humanity's richest source of prehistoric climate data. In layer upon layer of chemically distinctive water are traces of past atmospheres and ecosystems, forest fires and earthquakes and solar variation. They're ubiquitous in climate research; they're also beautiful. Images: Above) Ice core close-up. (American Museum of Natural History) Below) Inside the U.S. Geological Survey National Ice Core Lab. (USGS)