segunda-feira, 15 de dezembro de 2014

10 links úteis do Google que todos deviam conhecer

 

Você sabia que é possível criar uma conta do Google usando um email qualquer, sem que seja @gmail.com? – aliás você sabia que o Google sabe sua idade, sexo e interesses?  Conheça 10 links de acesso a diversas configurações, definições e funções que o buscador mais famoso do mundo oferece e que todos os seus usuários precisam conhecer.

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1. Criar uma nova conta do Google com qualquer email
Ao criar uma nova conta do Google, o processo padrão irá utilizar um endereço @gmail.com como nome da nova conta. Mas se você possuir outro email que utiliza habitualmente como "username", poderá fazê-lo usando o seguinte endereço para criar uma conta do Google.

https://accounts.google.com/SignUpWithoutGmail

2. Definições da publicidade
Às vezes esquecemos (ou nem sabemos) de quanto o Google sabe sobre nós. O Google recorre a diversas formas para descobrir tudo o que pode sobre seus usuários (como o perfil do Google+), incluindo a idade, sexo e interesses para apresentar publicidade direcionada em sites que você costuma visitar. O seguinte endereço revela o que o Google sabe sobre cada usuário.

https://www.google.com/ads/preferences/

3. Exportar todos os dados
Se alguma vez sentir necessidade de mudar para outros serviços, o Google disponibiliza uma ferramenta para exportação de emails, fotos, vídeos do YouTube entre outros. Para isso, basta acessar o Google Takeout para ter acesso a estas informações.

https://www.google.com/takeout

4. Fazer queixa de conteúdos copiados
Se existir conteúdos copiados na Internet sem acesso a fontes de origem ou até mesmo de forma não autorizada, há um local especial para fazer uma queixa DMCA, indicando para que o Google remova esses conteúdos e penalize os sites que o fizeram.

https://support.google.com/legal

5. Ver o histórico de localização
Ao utilizar algum dispositivo móvel como Android ou um iPhone com o serviço de localização do Google ativado poderão ficar assustados com aquilo que o Google acumula sobre vocês. Uma visita a esta URL permite saber por quais locais andamos hoje, ontem, semana passada… ou em qualquer outro dia do passado. – aqui é possível exportar estes dados em arquivos KML que poderão ser vistos no Google Earth e Google Drive.

https://maps.google.com/locationhistory

6. Ver histórico das pesquisas
O buscador Google registra cada termo de pesquisa que você já digitou em suas caixa de pesquisa. Ele ainda mantém um registro de todos os anúncios que você tenha clicado em vários sites do Google que possuem o serviço Google Adsense.

https://history.google.com

7. Mudar tempo de inatividade e definir mensagem "após a morte"
Se não fizerem login na em sua conta Google por um período de 9 meses, o Google poderá encerrar essa conta. No entanto é possível alterar para um período de 3 a 18 meses. – aqui também há a possibilidade de definir uma mensagem automática para que seja enviada, caso de não fizerem um login durante determinado tempo – sim, é aqui que podemos definir uma mensagem de "adeus", caso você pretenda partir deste plano.

https://www.google.com/settings/account/inactive

8. Verificar atividade suspeita em nossa conta
Preocupado que alguém esteja usando sua conta do Google? Acesse o relatório de atividades para ver os registros de todos os dispositivos recentemente utilizados para entrar em sua conta do Google. Você também poderá saber quais foram os endereço IP e sua localização geográfica aproximada.

https://security.google.com/settings/security/activity

9. Lista de apps, extensões e scripts com acesso aos nossos dados
Muitas vezes, apps e sites pedem acesso a alguns dados do Google. Na maioria das vezes esquecemos da quantidade que vai acumulando, mas este link mostrará todos. Ideal para visitar de vez em quando e remover tudo aquilo que já não for mais interessante ou não for mais útil (incluindo dispositivos Android/iOS dos quais você nem utiliza mais, mas que ainda lá permanecem).

https://security.google.com/settings/security/permissions

10. Reset da senha de administração para usuários do Google Apps
Para os usuários do serviço Google Apps, no caso de algum hacker se apoderar de nossa conta, podemos fazer um reset da senha de administração. Para isso teremos que confirmar que somos os legítimos donos do domínio em questão, criando um registro CNAME no gerenciador de DNS de nosso domínio.

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https://admin.google.com/SEUDOMINIO.COM.BR/VerifyAdminAccountPasswordReset

Via: AAM

 

ESA and Omega create new astronaut watch

 

The Speedmaster Skywalker X-33 is designed for use by astronauts (Photo: Omega)

The Speedmaster Skywalker X-33 is designed for use by astronauts (Photo: Omega)

Image Gallery (4 images)

If there's one steady market for wristwatches, it's astronauts. Omega watches, for example, have flown on manned space missions since the Omega Speedmaster Professional Chronograph was carried on Project Mercury in the early 1960s. Now the latest version, the Speedmaster Skywalker X-33, is seeing service on the International Space Station (ISS). Based on a patented idea by ESA astronaut Jean-François Clervoy, the timepiece is not only made to withstand the rigors of space, but also to carry out functions useful to space travelers.

The Omega Speedmaster Skywalker X-33 is an advance on the Swiss watchmaker's Speedmaster Professional X-33 and uses Omega's calibre 5619 advanced multi-functional quartz chronograph movement with a thermo-compensated integrated circuit and upgraded software. This is encased in a 45-mm, Grade 2, brushed titanium case with brushed crown and pushers, a ceramic bezel featuring a chromium nitride scale, and a 60-minute indicator marked by luminescent white Super-LumiNova with green emission.

The dial is a digital/analog readout with skeletonized black and white hour and minute hands coated with Super-LumiNova, and a red second hand. The dial itself is black with white indexes and hour markers, and an LCD readout with grey characters. One problem is digital/analog displays is that the analog hands tend to get in the way of the digital display, but the Skywalker disengages the hands on command to clear the display.

Jean François Clervoy on STS-103 (Photo: NASA)

Jean François Clervoy on STS-103 (Photo: NASA)

Having flown in space three times in the 1990s, Clervoy came upon an idea for improving wristwatches so they could track mission events in a way suitable for astronauts. The Skywalker's Mission Elapsed Time (MET) and Phase Elapsed Time (PET) allow astronauts to set mission time or the time for a task for any date in the past or future and calculate how much time remains or has elapsed. In addition, there are 19 functions including multiple alarms with different ringtones, time zones, perpetual calendar, chronograph, and countdown functions.

ESA holds the patents on the Skywalker, and though it is not involved in the watch's manufacture or sale, Omega is operating under license, and the space agency did subject the timepiece to rigorous testing to see if it was suitable for space duty. Carrying out tests at ESA's ESTEC technical center in Noordwijk, the Netherlands, and at a nuclear testing facility in Sweden under the supervision of France’s ONERA/DESP aerospace center, the Skywalker was subjected to vibrations and accelerations simulating a space vehicle launch, vacuum, temperatures from minus 45° C (minus 49° F) to 75° C (167° F), and simulated space radiation.

"We are delighted that our friends at the European Space Agency have tested and qualified the Speedmaster Skywalker X-33 for all its piloted missions, which is a natural extension of our long relationship with NASA and its space programme," says President of Omega, Stephen Urquhart. "ESA’s abilities and ambitions are extraordinary, as demonstrated by their recent high-profile successes with Rosetta and Philae, and we are proud that their name and endorsement grace the back of this iconic chronograph."

The Omega Speedmaster Skywalker X-33 sells for US$5,900.

Source: ESA

 

Organic blood-oxygen sensor can be stuck on like a Band-Aid

 

A sensor made from organic materials can be worn like a Band-Aid to track blood oxygen lev...

A sensor made from organic materials can be worn like a Band-Aid to track blood oxygen levels (Image: UC Berkeley/Yasser Khan)

Maintaining a steady blood oxygen level is critical for the body to stave off breathing problems and organ trouble. For those needing to keep a close eye on things, there's no shortage of monitoring systems and dedicated pulse oximeters available, but these can be somewhat unwieldy. Scientists at the University of California (UC) Berkeley are looking to make the process a little less cumbersome with the development of a thin, blood-oxygen sensor that can be worn much like a Band-Aid.

Typical pulse oximeters rely on LEDs that shoot both infrared and red light through certain parts of the body, usually a fingertip or earlobe, with a sensor waiting on the receiving end to gauge how much makes it through. As blood that is rich in oxygen absorbs more infrared light, and darker low-oxygen blood absorbs more red light, the sensor assesses the ratio of the two as they come out the other side and gains an indication of the blood's oxygen levels.

The UC Berkeley team instead used red and green light, which they say are comparably effective in determining oxygen levels in the blood. These green and red LEDs are made from organic materials and were integrated onto a flexible piece of plastic. The researchers tested the prototype alongside conventional pulse oximeters and discovered the readings to be equally accurate.

“We showed that if you take measurements with different wavelengths, it works, and if you use unconventional semiconductors, it works,” says Ana Arias, associate professor of electrical engineering and computer sciences and head of the UC Berkeley. “Because organic electronics are flexible, they can easily conform to the body.”

One other advantage of the newly developed sensors is that they are much cheaper to manufacture than the conventional versions. Rather than needing to disinfect them for repeated use, the researchers say that the organic sensors could be cheap enough to warrant one-time use before disposal.

The research findings were published in the journal Nature Communications.

Source: UC Berkeley

 

 

NuDown inflatable jackets insulate with air

 

NuDown NuTech uses a hand pump to adjust insulation level

NuDown NuTech uses a hand pump to adjust insulation level

Image Gallery (7 images)

Back in 2009, Utah-based company Klymit came up with a wild idea for cold-weather clothing: replace traditional insulation with gas. Its NobleTek inflatable clothing earned plenty of attention from the outdoor and technology industries, but it never really seemed to catch on. Under the guidance of start-up NuDown, the inflatable insulation has been repackaged into a simpler form. In place of a mandatory argon gas inflator, it now uses a simple hand pump to adjust your core warmth.

Klymit's original argon-driven insulation, seen on garments like the Ulaar jacket, was designed to offer some clear benefits over traditional fill insulation materials like goose down and Primaloft. It offered the wearer the ability to adjust the garment's warmth level throughout the day, adding versatility without so much emphasis on layering. Unlike traditional down insulation, which never worked well when wet, NobleTek worked wet or dry. The lightweight system also made for highly packable garments – instead of a big, puffy jacket, you could slide a deflated shell into your backpack or suitcase.

For a design as unconventional as blow-up winter clothing to catch on, it should offer a seamless user experience with little to no downside. NobleTek didn't. It had one really glaring issue that made it feel like a geeky, high-tech "solution" that introduced more problems than it solved. On top of selling you a pricy jacket, Klymit expected you to pay to essentially renew your insulation every time you ran out of argon canisters – not an attractive alternative to buying a down or Primaloft jacket once ... without having to pay for new insulation every couple months. A three-pack of argon canisters costs US$20, so argon isn't exactly cheap, either.

Beyond the added money spent on buying new cartridges, the system introduced an unnecessary amount of hassle. I tested one of the original Klymit vests, and for the rare occasion in which I wanted to take advantage of the advanced insulation adjustability, there were about 10 where I just wanted to grab a warm (and simple) piece of insulation and go outside, instead of spending time searching for an unused argon canister, pumping the vest, readjusting, etc. Maybe my personal climate just isn't that touchy, but the versatility didn't come close to winning out over the added hassle. I'd choose a regular down or fleece vest every time.

Long story short, Klymit's NobleTek was an intriguing idea with lackluster execution, which may or may not have had something to do with Klymit turning its attention toward more traditional inflatables, like sleeping pads and packrafts, as well as non-inflatable outdoor gear. In 2013, it sold the apparel side of its business to entrepreneur Jeff Pickett, who founded Reno-based NuDown. The spin-off has been offering Klymit's argon-based inflation jacket and vest designs, but it's preparing to launch a new line of inflatable garments that might just prove a bit more user-friendly.

NuTech will be available on three men's and women's styles in 2015

NuTech, as NuDown is calling it, drops the annoying argon canisters in favor of regular old air. Each vest and jacket is equipped with a pocket-sized hand pump that lets the wearer pump things up for a higher insulation level and greater warmth. A release valve bleeds air for cooling down.

NuDown estimates that a single pump increases warmth by about a single degree in Fahrenheit. It says that 20 pumps will keep you warm on "slightly chilly days," with 30 to 40 pumps dialing things up for colder winter weather. Argon canisters can still be used with purchase of an optional $39 argon upgrade kit, and NuDown suggests that argon is a good option for the coldest days of 20º F (-7º C) and below.

NuTech enjoys the same versatility and packability benefits of the argon-based design without the need to replace canisters. There will still be a bit of extra pumping and tweaking when compared to an old fashioned puffy, but the new design seems to have tackled the biggest drawback of NobleTek.

Of course, air may not offer the same type of warmth as argon. Klymit expended a lot of effort in marketing argon as a superior form of insulation, offering three times the insulation power of the air trapped by natural and synthetic insulations. NuDown's materials suggest it's hedging its bets, still touting the superiority of argon while suggesting that air is sufficient for most winter weather. Hitting temperatures of 20º F really isn't that uncommon, so will air be up to the challenge of insulating the average user throughout the winter, or will many end up having to buy argon (or use a different insulating garment) to keep warm?

Research in the drysuit industry, where air and argon are used as insulations, suggests that there is no discernible difference between the two in thermal-regulating performance. Whether that holds true on a winter jacket/vest remains to be seen.

NuDown plans to show half a dozen NuTech vest and jacket designs at the upcoming Outdoor Retailer Winter Market and SIA Snow Show trade shows in January. It will bring the three men's and three women's styles to market in Northern Hemisphere Fall 2015, with prices between $400 and $600. So while you won't necessarily have to spend money down the line on argon canisters, you'll spend about 60 percent more up front, over the $250 to $350 prices of NuDown's current argon designs. Those high prices ($400 for a vest?) are exacerbated by the fact that you'll no longer be buying your way into something kind of techy and cutting edge – your $600 jacket will be insulated with air, the stuff you breathe every second of every day ... for free. Why shouldn't it be cheaper than the argon-based styles?

Judging from the sketches in the press release, at least part of the new lineup will escape the rough look of external air bubbles that plagued Klymit and NuDown garments past and present (like the ones in the photos). Some of the new jackets look more like classic shells on the outside, with the air chambers underneath. They will include technical features like waterproof/windproof fabric, fleece stretch panels, anti-odor charcoal wicking liners and RECCO avalanche safety reflectors.

Still, unless NuDown dramatically reworks its pricing structure, Old Down looks better than ever.

Source: NuDown via The GearCaster

 

A Tool for Today’s Complex Health Challenges

 

Mon, 12/15/2014 - 11:06am

Waters Corp.

Nearly half of all U.S. adults, nearly 117 million individuals, are living with one or more chronic health conditions. This has become the age of chronic disease, and achieving better outcomes depends on developing tools for research and clinical care that efficiently and accurately address the complex diseases we face today.

A century ago, chronic diseases caused less U.S. mortalities, compared to influenza, pneumonia and other infectious diseases, which struck quickly and often at a young age. In 1900, the average life expectancy in the U.S. was just 47 years. Today, that number is nearly 80. Our longevity is no longer determined by our ability to dodge or defeat infectious disease, but by a complex combination of genetic and environmental factors that lead to chronic health conditions including cancer, diabetes and heart disease.

The increase in our life expectancy is an impressive achievement for our health care system, as well as a threat to its stability. As Americans live longer, our health care consumption increases. The share of U.S. gross domestic product dedicated to health care spending rose to 16% in 2008 from just 9% in 1980. It’s critical that we improve our ability to manage the costs of these chronic conditions, or ideally, to prevent them in the first place.

Progress in reducing the frequency and burden of these conditions can be accelerated with the development of highly predictive diagnostic tests that accurately forecast the health conditions a person is genetically predisposed to developing. Due to the complex interaction of genetic factors, along with environmental influences to describe one’s phenotype, scientific research is increasingly demonstrating that genotypic information alone is insufficient to wholly describe a patient’s health status; rather it’s imperative to complement genotypic state with phenotypic information by measuring a patient’s proteome, metabolome and microbiome. This information will be key to identifying preventative measures that are best suited for each individual so we can improve both the length and quality of life.

This is the promise of personalized or precision medicine, and realizing its potential for routine clinical care requires us to make significant progress on two very difficult tasks simultaneously. The first is to greatly expand our understanding of which panels of biomarkers indicate risk for a particular disease. The second is to translate the growing catalogue of biomarker panels into reliable diagnostics that can fit seamlessly into physician workflows.

Mass spectrometry, combined with genetic testing, is our best chance to be successful at both tasks. It’s the bridge between the basic science of disease and the development of clinical diagnostics. It’s the most powerful analytical tool for measuring the proteome, metabolome and microbiome.

For both the researchers seeking to identify new biomarkers and the physicians eager to leverage that information for care in real-world clinical settings, the early tools developed for analyzing human  specimens aren’t powerful enough to digest the volume and complexity of biologic information that’s key to biomarker panel discovery and diagnostics development.

Existing methods are capable of testing a sample for only a few analytes at one time. Given the incredible complexity of our biochemical make-up, which requires us to look at proteomics, metabolomics, lipidomics and microbiomics, testing for individual analytes provides a limited set of information, artificially limiting our understanding of phenotypic status. 

Mass spectrometry’s power to transform research and diagnostic use is rooted in its capacity to test the same sample for an entire panel of biomarkers in a single pass, or—once an assay has been discovered—to test numerous samples for the same biomarkers. Equally as important, mass spectrometry is a highly selective and sensitive tool, which is critical to achieving the specificity and confident quantitative measurement that is required to discover and test for biomarkers.

For instance, tissue imaging pathology is an area where mass spectrometry may be particularly useful. Traditional methods are slow and subjective to user interpretation: Two different pathologists may interpret the same image of a stained tissue sample vastly differently. Mass spectrometry can deliver the tissue’s molecular fingerprint—and its status as healthy or diseased—in a single screen with consistent chemical objectivity.

The utility of mass spectrometry is already demonstrated in real-world clinical practice across a number of areas. For example, mass spectrometry is used to test for early metabolism risks in each of the approximately four million live births that take place in the U.S. each year. The screening examines hundreds of analytes, something unfeasible with traditional diagnostic methods. Mass spectrometry is also used in immunosuppressant drug monitoring following organ transplants to ensure a patient receives the appropriate dosage and doesn’t experience an overly compromised immune system. The specificity and sensitivity mass spectrometry delivers makes it uniquely suited to perform these diagnostic tasks.

For clinical researchers, mass spectrometry has the potential to accelerate the rate of biomarker discovery and broaden our knowledge of how our genetic code and environment interact. Instead of being limited to searching for less than a handful of analyte measures during each screening of a sample, research can use a mass spectrometer to measure as many as 50 analytes simultaneously. The analysis will also be more precise than traditional methods, which will also speed the research process.

A visionary use of mass spectrometry is the iKnife, or Intelligent Knife, which is a tool in development to analyze a human sample in real-time during surgery. During an operation to remove cancerous tissue, surgeons can be unsure of exactly where the diseased tissue ends and healthy tissue begins. The result is that healthy tissue is sometimes excised during the surgery, or worse, parts of a tumor are missed and a follow up operation must be scheduled to remove the remaining malignant tissue.

The conceptual stage iKnife, based on rapid evaporative ionization mass spectrometry (REIMS) technology, integrates with a standard electrosurgical tool, collecting and analyzing the resulting smoke to instantly determine the status of the excised tissue. The ability of mass spectrometry to quickly and accurately determine the status of human tissue has the potential to one day transform surgical interventions.

The potential impact of mass spectrometry has supported a growing number of pioneers in the space.  Waters, city, state, co-founded the National Phenome Centre at Imperial College London. Plans are underway to partner with other institutions to create a network of phenome centers with locations across the globe. The networks’ discoveries, and the work of researchers and clinicians across the medical profession, will help realize the potential for mass spectrometry to help transform health care.

Innovation in diagnostics that leads to personalized medicine ranks among the most challenging tasks facing the health care community. Mass spectrometry is the most promising tool to achieving the goal of providing each individual with the health care that best fits their unique biochemical makeup.

HP Will Release a “Revolutionary” New Operating System in 2015

 

Hewlett-Packard’s ambitious plan to reinvent computing will begin with the release of a prototype operating system next year.

 

By Tom Simonite on December 8, 2014

Why It Matters

U.S. data centers consumed 91 billion kilowatt-hours of electricity in 2013—twice as much as all the households in New York City—according to the Natural Resources Defense Council.

Closeup of HP Memristor devices on a 300 millimeter wafer.

Hewlett-Packard will take a big step toward shaking up its own troubled business and the entire computing industry next year when it releases an operating system for an exotic new computer.

The company’s research division is working to create a computer HP calls The Machine. It is meant to be the first of a new dynasty of computers that are much more energy-efficient and powerful than current products. HP aims to achieve its goals primarily by using a new kind of computer memory instead of the two types that computers use today. The current approach originated in the 1940s, and the need to shuttle data back and forth between the two types of memory limits performance.

“A model from the beginning of computing has been reflected in everything since, and it is holding us back,” says Kirk Bresniker, chief architect for The Machine. The project is run inside HP Labs and accounts for three-quarters of the 200-person research staff. CEO Meg Whitman has expanded HP’s research spending in support of the project, says Bresniker, though he would not disclose the amount.

The Machine is designed to compete with the servers that run corporate networks and the services of Internet companies such as Google and Facebook. Bresniker says elements of its design could one day be adapted for smaller devices, too.

HP must still make significant progress in both software and hardware to make its new computer a reality. In particular, the company needs to perfect a new form of computer memory based on an electronic component called a memristor (see “Memristor Memory Readied for Production”).

A working prototype of The Machine should be ready by 2016, says Bresniker. However, he wants researchers and programmers to get familiar with how it will work well before then. His team aims to complete an operating system designed for The Machine, called Linux++, in June 2015. Software that emulates the hardware design of The Machine and other tools will be released so that programmers can test their code against the new operating system. Linux++ is intended to ultimately be replaced by an operating system designed from scratch for The Machine, which HP calls Carbon.

Programmers’ experiments with Linux++ will help people understand the project and aid HP’s progress, says Bresniker. He hopes to gain more clues about, for example, what types of software will benefit most from the new approach.

The main difference between The Machine and conventional computers is that HP’s design will use a single kind of memory for both temporary and long-term data storage. Existing computers store their operating systems, programs, and files on either a hard disk drive or a flash drive. To run a program or load a document, data must be retrieved from the hard drive and loaded into a form of memory, called RAM, that is much faster but can’t store data very densely or keep hold of it when the power is turned off.

HP plans to use a single kind of memory—in the form of memristors—for both long- and short-term data storage in The Machine. Not having to move data back and forth should deliver major power and time savings. Memristor memory also can retain data when powered off, should be faster than RAM, and promises to store more data than comparably sized hard drives today.

The Machine’s design includes other novel features such as optical fiber instead of copper wiring for moving data around. HP’s simulations suggest that a server built to The Machine’s blueprint could be six times more powerful than an equivalent conventional design, while using just 1.25 percent of the energy and being around 10 percent the size.

HP’s ideas are likely being closely watched by companies such as Google that rely on large numbers of computer servers and are eager for improvements in energy efficiency and computing power, says Umakishore Ramachandran, a professor at Georgia Tech. That said, a radical new design like that of The Machine will require new approaches to writing software, says Ramachandran.

There are other prospects for reinvention besides HP’s technology. Companies such as Google and Facebook have shown themselves to be capable of refining server designs. And other new forms of memory, all with the potential to make large-scale cloud services more efficient, are being tested by researchers and nearing commercialization (see “Denser, Faster Memory Challenges Both DRAM and Flash” and “A Preview of Future Disk Drives”).

“Right now it’s not clear what technology is going to become useful in a big way,” says Steven Swanson, an associate professor at the University of California, San Diego, who researches large-scale computer systems.

HP may also face skepticism because it has fallen behind its own timetable for getting memristor memory to market. When the company began working to commercialize the components, together with semiconductor manufacturer Hynix, in 2010, the first products were predicted for 2013 (see “Memristor Memory Readied for Production”).

Today, Bresniker says the first working chips won’t be sent to HP partners until 2016 at the earliest.

source: www.technologyreview.com

Your Smartphone Could Soon Listen for Sleep Disorders

 

Researchers say they’ve come up with an accurate, simple way to monitor breathing while you sleep, no wearables required.

 

By Rachel Metz on December 12, 2014

 

Researchers are working on a more convenient way to track your breathing while you sleep: by putting a microphone-equipped pair of earphones and a smartphone on your bedside table. The technology could make tracking sleep disorders easier than visiting a sleep lab.

A team at Stevens Institute of Technology and Florida State University conducted a six-month study in which earbuds that included an in-line microphone were plugged into an iPhone that recorded sounds as six people slept. The researchers say that even with the earphones placed on a table next to the bed, they were able to use the microphone to monitor participants’ breathing to within half a breath per minute of what could be recorded with a chest-worn respiration monitor and a microphone clipped to participants’ collars.

Yingying Chen, an associate professor at Stevens, says researchers plan to release a smartphone app related to their work next year.

Such an app could make it easier and cheaper to accurately keep tabs on the quality of your sleep than sensor-laden wristbands or devices that sit on or beneath the mattress. Despite immense growth in the capabilities and sheer number of consumer-geared wearable activity trackers, they can be uncomfortable to wear or use, and accuracy varies.

Chen also hopes the work can help diagnose health problems like sleep apnea. Typically, such problems are studied at hospitals, where sensors are attached to a patient’s body and snoozing is monitored by medical professionals. Chen contends that it can be hard for doctors to capture irregular patterns in this kind of setting.

In their study, researchers tested the sensitivity of the microphone on the earbuds for recording breathing rate, and also modified the earbuds to act as additional microphones that recorded in mono and stereo. The researchers filtered out ambient noise to focus on breathing and other actions that occurred during sleep, like snoring and coughing.

While the breathing rate was measured most accurately when the earphone was worn or kept next to a participant’s pillow and multiple microphones were used, the study also shows it worked well with just the unmodified earphones on a bedside table.

Andrew Campbell, a computer science professor at Dartmouth College who co-directs the Dartmouth Networking and Ubiquitous Systems Laboratory, says the work is “very cool” but points out it could be difficult to measure respiratory signals if more than one person is sleeping in the same bed.

This problem could be overcome because many phones are now built with several microphones to aid in noise cancellation. “Ultimately if the microphone on the phone could evolve to do this sensing without the earbud, that would be great,” he says.

A paper on the technology will be presented at the IEEE Infocom conference in April.