Social media snaps map the sweep of Japan’s cherry blossom season in unprecedented detail
Dyer
Social media contains enormous amounts of data about people, our everyday lives, and our interactions with our surroundings. As a byproduct, it also contains a vast trove of information about the natural world.
In a new study published in Flora, we show how social media can be used for “incidental citizen science”. From photos posted to a social site, we mapped countrywide patterns in nature over a decade in relatively fine detail.
Our case study was the annual spread of cherry blossom flowering across Japan, where millions of people view the blooming each year in a cultural event called “hanami”. The flowering spreads across Japan in a wave (“sakura zensen” or 桜前線) following the warmth of the arriving spring season.
The hanami festival has been documented for centuries, and research shows climate change is making early blossoming more likely. The advent of mobile phones – and social network sites that allow people to upload photos tagged with time and location data – presents a new opportunity to study how Japan’s flowering events are affected by seasonal climate.
Why are flowers useful to understand how nature is being altered by climate change?
Many flowering plants, including the cherry blossoms of Japan (Prunus subgenus Cerasus), require insect pollination. To reproduce, plant flowers bloom at optimal times to receive visits from insects like bees.
Temperature is an important mechanism for plants to trigger this flowering. Previous research has highlighted how climate change may create mismatches in space or time between the blooming of plants and the emergence of pollinating insects.
It’s been difficult for researchers to map the extent of this problem in detail, as its study requires simultaneous data collection over large areas. The use of citizen science images deliberately, or incidentally, uploaded to social network sites enables big data solutions.
How did we conduct our study?
We collected images from Japan uploaded to Flickr between 2008 and 2018 that were tagged by users as “cherry blossoms”. We used computer vision techniques to analyse these images, and to provide sets of keywords describing their image content.
Next, we automatically filtered out images appearing to contain content that the computer vision algorithms determined didn’t match our targeted cherry blossoms. For instance, many contained images of autumn leaves, another popular ecological event to view in Japan.
The locations and timestamps of the remaining cherry blossom images were then used to generate marks on a map of Japan showing the seasonal wave of sakura blossoms, and to estimate peak bloom times each year in different cities.
Checking the data
An important component of any scientific investigation is validation – how well does a proposed solution or data set represent the real-world phenomenon under study?
Our study using social network site images was validated against the detailed information published by the Japan National Tourism Organisation.
We also manually examined a subset of images to confirm the presence of cherry flowers.
Plum flowers (Prunus mume) look very similar to cherry blossoms, especially to tourists, and they’re frequently mistaken and mislabelled as cherry blossoms. We used visible “notches” at the end of cherry petals, and other characteristics, to distinguish cherries from plums.
Taken together, the data let us map the flowering event as it unfolds across Japan.
Out-of-season blooms
Our social network site analysis was sufficiently detailed to accurately pinpoint the annual peak spring bloom in the major cities of Tokyo and Kyoto, to within a few days of official records.
Our data also revealed the presence of a consistent, and persistent, out-of-season cherry bloom in autumn. Upon further searching, we discovered that this “unexpected” seasonal bloom had also been noted in mainstream media in recent years. We thus confirmed that this is a real event, not an artefact of our study.
So, even without knowing it, many of us are already helping to understand how climate change influences our environment, simply by posting online photographs we capture. Dedicated sites such as Wild Pollinator Count are excellent resources to contribute to the growing knowledge base.
The complex issues of climate change are still being mapped. Citizen science allows our daily observations to improve our understanding, and so better-manage our relationship with the natural world.
This article originally appeared on The Conversation.
About the Authors
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Adrian dyer
Adjunct Research Fellow, Department of Physiology, Faculty of Medicine, Nursing and Health Sciences
Adrian is a vision scientist and photographer. He’s interested in the comparative physiology of how different animals evolved their visual capabilities depending on the ecology of their environment, and the information that can be learnt to improve the design of new systems. He received a PhD in 2000 for developing computational models of how bees use colour vision, and was awarded an Alexander von Humboldt Fellowship to study bees in Germany. Then at Cambridge University (UK), he studied how bee interactions with plants may be influenced by climatic conditions, before being awarded an ARC QEII Fellowship at Monash University to research with computational models how bee pollination may be impacted by climate change. He currently researches technology solutions derived from bees and the environment to improve digital solutions to complex problems.
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Alan dorin
Associate Professor, Department of Data Science and AI, Monash Data Futures Institute
Alan researches the ways in which technology assists discovery in the ecological sciences and in human creativity. Through his work in artificial life and ecological simulation, Alan explores the key attributes of organisms that enable them to live in complex environments. This knowledge is used to improve agriculture and horticulture, and to assist us in maintaining natural ecosystems. Alan promotes an understanding of the relationships between technology and human endeavour by nurturing curiosity, and encouraging students to form their own bridges between disciplines.
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Carolyn vlasveld
PhD Candidate, School of Biological Sciences
Carolyn is a botanist and PhD candidate in the School of Biological Sciences. Her main research interests are in plant ecology and evolutionary biology, diversity in leaf traits, eucalypts, and leaf heteroblasty.
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Moataz elqadi
Adjunct Researcher, Faculty of Information Technology
Moataz builds solutions for problems using data science, machine learning, and cloud computing. His experience spans ecology, telecom, government, transportation, and education. He’s comfortable working across disciplinary and cultural boundaries.
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