Why does a leap year have 366 days?


You may be used to hearing that it takes the Earth 365 days to make a full lap, but that journey actually lasts about 365 and a quarter days. Leap years help to keep the 12-month calendar matched up with Earth’s movement around the Sun.

After four years, those leftover hours add up to a whole day. In a leap year, we add this extra day to the month of February, making it 29 days long instead of the usual 28.

The idea of an annual catch-up dates back to ancient Rome, where people had a calendar with 355 days instead of 365 because it was based on cycles and phases of the Moon. They noticed that their calendar was getting out of sync with the seasons, so they began adding an extra month, which they called Mercedonius, every two years to catch up with the missing days.

In the year 45 B.C.E., Roman emperor Julius Caesar introduced a solar calendar, based on one developed in Egypt. Every four years, February received an extra day to keep the calendar in line with the Earth’s journey around the Sun. In honor of Caesar, this system is still known as the Julian calendar.

But that wasn’t the last tweak. As time went on, people realized that the Earth’s journey wasn’t exactly 365.25 days – it actually took 365.24219 days, which is about 11 minutes less. So adding a whole day every four years was actually a little more correction than was needed.

In 1582, Pope Gregory XIII signed an order that made a small adjustment. There would still be a leap year every four years, except in “century” years – years divisible by 100, like 1700 or 2100 – unless they were also divisible by 400. It might sound a bit like a puzzle, but this adjustment made the calendar even more accurate – and from that point on, it was known as the Gregorian calendar.

What if we didn’t have leap years?

If the calendar didn’t make that small correction every four years, it would gradually fall out of alignment with the seasons. Over centuries, this could lead to the solstices and equinoxes occurring at different times than expected. Winter weather might develop in what the calendar showed as summer, and farmers could become confused about when to plant their seeds.

Without leap years, our calendar would gradually become disconnected from the seasons.

Other calendars around the world have their own ways of keeping time. The Jewish calendar, which is regulated by both the Moon and the Sun, is like a big puzzle with a 19-year cycle. Every now and then, it adds a leap month to make sure that special celebrations happen at just the right time.

The Islamic calendar is even more unusual. It follows the phases of the Moon and doesn’t add extra days. Since a lunar year is only about 355 days long, key dates on the Islamic calendar move 10 to 11 days earlier each year on the solar calendar.

For example, Ramadan, the Islamic month of fasting, falls in the ninth month of the Islamic calendar. In 2024, it will run from March 11 to April 9; in 2025, it will occur from March 1-29; and in 2026, it will be celebrated from Feb. 18 to March 19.

Learning from the planets

Astronomy originated as a way to make sense of our daily lives, linking the events around us to celestial phenomena. The concept of leap years exemplifies how, from early ages, humans found order in conditions that seemed chaotic.

Simple, unsophisticated but effective tools, born from creative ideas of ancient astronomers and visionaries, provided the first glimpses into understanding the nature that envelops us. Some ancient methods, such as astrometry and lists of astronomical objects, persist even today, revealing the timeless essence of our quest to understand nature.

Ancient Egyptians were dedicated astronomers. This section from the ceiling of the tomb of Senenmut, a high court official in Egypt, was drawn sometime circa 1479–1458 B.C.E. It shows constellations, protective gods and 24 segmented wheels for the hours of the day and the months of the year. NebMaatRa/Wikimedia, CC BY

People who do research in physics and astronomy, the field that I study, are inherently curious about the workings of the universe and our origins. This work is exciting, and also extremely humbling; it constantly shows that in the grand scheme, our lives occupy a mere second in the vast expanse of space and time – even in leap years when we add that extra day.

Hello, curious kids! Do you have a question you’d like an expert to answer? Ask an adult to send your question to CuriousKidsUS@theconversation.com. Please tell us your name, age and the city where you live.

And since curiosity has no age limit – adults, let us know what you’re wondering, too. We won’t be able to answer every question, but we will do our best.The Conversation

Bhagya Subrayan, PhD Student in Physics and Astronomy, Purdue University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Read More........ Categories: ,,,

Warehouse robot kills 90% of viruses

Researchers at MIT's Computer Science and Artificial Intelligence Laboratory (CSAIL), in collaboration with Ava Robotics and the Greater Boston Food Bank (GBFB), have designed a new robotic system that kills microorganisms in its proximity, using ultraviolet light.

During tests at GBFB, the robot drove by pallets and storage aisles at 0.22 miles per hour. At this speed, the robot could cover a 4,000-square-foot warehouse space in just half an hour. Ultraviolet C (UV-C) is a subtype of ultraviolet light that is short-wavelength (100–280 nm) and germicidal. Its light can kill or inactivate microorganisms by destroying nucleic acids and disrupting DNA or RNA. The dosage emitted by the robot seen here neutralised 90% of coronaviruses (and other organisms) on the warehouse surfaces. The results are encouraging enough that the approach could be useful for autonomous UV disinfection in other environments – such as airplanes, factories, restaurants, schools, and supermarkets, according to the researchers. Since UV-C is dangerous for all living organisms, however, it can only operate when nobody is around. MIT designed the UV-C light fixture, which then became integrated with Ava Robotics' mobile robot base. The complete system can map a space and navigate between waypoints and other pre-specified areas. While most effective in the direct "line of sight," the machine can get to nooks and crannies as the light bounces off surfaces. "Our 10-year-old warehouse is a relatively new food distribution facility with AIB-certified, state-of-the-art cleanliness and food safety standards," explained Catherine D'Amato, President of the Greater Boston Food Bank. "COVID-19 is a new pathogen that GBFB, and the rest of the world, was not designed to handle. We are pleased to have this opportunity to work with MIT CSAIL and Ava Robotics to innovate and advance our sanitation techniques to defeat this menace." Food banks are facing a particular demand due to the stress of COVID-19. The United Nations estimates that, because of the virus, the number of people facing severe food insecurity worldwide could double to 265 million. In the U.S. alone, the five-week total of job losses has risen to 26 million, potentially pushing millions more into food insecurity. "Food banks provide an essential service to our communities, so it is critical to help keep these operations running," said Alyssa Pierson, CSAIL research scientist and technical lead of the UV-C lamp assembly. "Here, there was a unique opportunity to provide additional disinfecting power to their current workflow and help reduce the risks of COVID-19
exposure."A shipping area can change overnight, so the team is now researching how to use onboard sensors to adapt to new environments – teaching the robot to differentiate between occupied and unoccupied aisles, for example, so it can switch its path accordingly; and altering its speed to ensure the optimal UV dosage is applied to different objects and surfaces. Comments »Source: https://www.futuretimeline.net
Read More........ Categories: ,,,

IBM developing world's smallest computer

Credit: IBM Research
Most people are familiar with Moore's Law, but few have heard of Bell's Law – a related phenomenon coined by U.S. engineer Gordon Bell. This describes how a new class of computing devices tends to emerge about every decade or so, each 100 times smaller than the last. The shrinking volume of machines becomes obvious when you look back at the history of technology.

The 1960s, for example, were characterised by large mainframes that often filled entire rooms. The 1970s saw the adoption of "minicomputers" that were cheaper and smaller. Personal computing emerged in the early 1980s and laptops became popular in the 1990s. This was followed by mobile phones from the 2000s onwards, which themselves became ever thinner and more compact with each passing year, along with tablets and e-readers. More recently there has been rapid growth in wireless sensor networks that is giving birth to the Internet of Things (IoT).

The new computer announced by IBM is just 1mm x 1mm across, making it the smallest machine of its kind to ever be developed. It will feature as many as a million transistors, a solar cell and communications module. The company predicts these devices will be in widespread use within five years, embedded in all manner of everyday objects. So-called "cryptographic anchors" and blockchain technology will ensure a product's authenticity – from its point of origin to the hands of the customer. These high-tech, miniature watermarks will (for example) verify that products have originated from the factory the distributor claims they are from, and are not counterfeits mixed in with genuine items.

In some countries, nearly 70 percent of certain life-saving pharmaceuticals are counterfeit and the overall cost of fraud to the global economy is more than $600bn every year. This new generation of tiny computers will monitor, analyse, communicate and even act on data.

"These [crypto-anchor] technologies pave the way for new solutions that tackle food safety, authenticity of manufactured components, genetically modified products, identification of counterfeit objects and provenance of luxury goods," says IBM research chief, Arvind Krishna.

Looking further into the future – if Bell's Law continues – devices are likely to be small enough to fit inside blood cells within a few decades. The potential applications then will become like science fiction: could we see a merger between humans and machines?

Source: https://www.futuretimeline.net/
Read More........ Categories: ,,,
Subscribe to: Posts (Atom)