Over 100 years ago, Alexander Graham Bell challenged National Geographic readers to do something daring and fresh – “establish a brand new science.” He pointed out that there were already sciences based on the measurement of sound and light. But there was no science of smell. Bell challenged his readers to “measure a smell.”
Today, most smartphones in your pocket include impressive built-in features based on the science of sound and light-weight: voice assistants, facial recognition, and image enhancement. Smell science offers nothing prefer it. But that situation is changing, as advances in machine odor recognition, also called “digitized smell,” are finally answering Bell's call to motion.
Research into machine olfaction faces an enormous challenge since the human sense of smell is so complex. While human vision relies mainly on Receptor cells within the retina – rods and three varieties of cones – the smell is produced by about 400 varieties of Receptor cells within the nose.
The machine's sense of smell begins with sensors that detect and discover molecules within the air. These sensors serve the identical purpose because the receptors in your nose.
But to be useful to humans, machine olfaction must go one step further. The system must know what a specific molecule or group of molecules smells prefer to a human. To do that, machine olfaction needs machine learning.
Applying machine learning to smells
Machine learning, and particularly a variety of machine learning called deep learningis at the guts of notable advances reminiscent of voice assistants and facial recognition apps.
Machine learning can be key to digitizing smells because it may well learn to map the molecular structure of an odor-causing compound to textual smell descriptions. The machine learning model learns the words that folks typically use—for instance, “sweet” and “dessert”—to explain what they experience once they encounter certain odor-causing compounds, reminiscent of Vanillin.
But machine learning requires large data sets. The web offers an unimaginably great amount of audio, image, and video content that might be used to coach artificial intelligence systems that recognize sounds and pictures. Yet machine olfaction has long struggled with an information shortage, partly because most individuals cannot verbally describe smells as effortlessly and clearly as they will describe images and sounds. Without access to web-wide data sets, researchers have been unable to coach truly powerful machine learning models.
However, things began to vary in 2015 when researchers discovered the DREAM Odor Prediction ChallengeThe competition published Data collected from Andreas Keller And Leslie VosshallBiologists who study the sense of smell invited teams from all over the world to submit their machine learning models. The models needed to predict odor labels reminiscent of “sweet,” “flower,” or “fruit” for odor-producing compounds based on their molecular structure.
The strongest models were tested in a Article within the journal Science in 2017. A classic machine learning technique called random forestwhich mixes the outcomes of several decision tree flowcharts proved to be the winner.
I’m a Machine learning researchers with a long-standing interest in the applying of machine learning in chemistry and psychiatry. The DREAM challenge sparked my interest. I also felt a private connection to the sense of smell. My family has its roots within the small town of Kannauj in northern India, which India's perfume capital. In addition, my father is a chemist and has spent most of his profession analyzing geological samples, so machine olfaction presented an irresistible opportunity on the intersection of perfumery, culture, chemistry and machine learning.
Progress in machine olfaction research gained momentum after the completion of the DREAM Challenge. During the COVID-19 pandemic, many cases of Smell blindness or anosmiawere reported. The sense of smell, which normally takes a back seat, got here into public awareness. In addition, a research project that Pyrfume Projectmore and bigger data sets made publicly available.
Smell deep
By 2019, the most important datasets had grown from fewer than 500 molecules within the DREAM competition to about 5,000 molecules. A Google Research team led by Alexander Wiltschko it was finally possible to increase the deep learning revolution to the machine sense of smell. Their model, which is predicated on a variety of deep learning called Graph neural networksfounded State-of-the-art results in machine smelling. Wiltschko is now the founder and CEO of Osmowhose mission is to “give computers a sense of smell”.
Recently, Wiltschko and his team used a graph neural network to create a “Main odor map”, by which perceptually similar smells are placed closer together than dissimilar ones. This was difficult: small changes within the molecular structure can result in large changes within the perception of smell. Conversely, two molecules with very different molecular structures can still smell almost the identical.
Such advances in deciphering the smell code will not be only intellectually exciting, but in addition offer promising applications, including personalized perfumes and smells, higher insect repellents, novel chemical sensors, early disease detection, and more realistic augmented reality experiences. The way forward for machine olfaction looks shiny. And it guarantees to smell good, too.
image credit : theconversation.com
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