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  • ✇IEEE Spectrum
  • Engineering the First Fitbit: The Inside StoryTekla S. Perry
    It was December 2006. Twenty-nine-year-old entrepreneur James Park had just purchased a Wii game system. It included the Wii Nunchuk, a US $29 handheld controller with motion sensors that let game players interact by moving their bodies—swinging at a baseball, say, or boxing with a virtual partner. Park became obsessed with his Wii. “I was a tech-gadget geek,” he says. “Anyone holding that nunchuk was fascinated by how it worked. It was the first time that I had seen a compelling consumer u
     

Engineering the First Fitbit: The Inside Story

7. Srpen 2024 v 15:00


It was December 2006. Twenty-nine-year-old entrepreneur James Park had just purchased a Wii game system. It included the Wii Nunchuk, a US $29 handheld controller with motion sensors that let game players interact by moving their bodies—swinging at a baseball, say, or boxing with a virtual partner.

Park became obsessed with his Wii.

“I was a tech-gadget geek,” he says. “Anyone holding that nunchuk was fascinated by how it worked. It was the first time that I had seen a compelling consumer use for accelerometers.”

After a while, though, Park spotted a flaw in the Wii: It got you moving, sure, but it trapped you in your living room. What if, he thought, you could take what was cool about the Wii and use it in a gadget that got you out of the house?

A clear plastic package contains a first-generation black Fitbit. Text reads \u201cFitbit,\u201d \u201cWireless Personal Tracker\u201d, and \u201cTracks your fitness & sleep\u201d The first generation of Fitbit trackers shipped in this package in 2009. NewDealDesign

“That,” says Park, “was the aha moment.” His idea became Fitbit, an activity tracker that has racked up sales of more than 136 million units since its first iteration hit the market in late 2009.

But back to that “aha moment.” Park quickly called his friend and colleague Eric Friedman. In 2002, the two, both computer scientists by training, had started a photo-sharing company called HeyPix, which they sold to CNET in 2005. They were still working for CNET in 2006, but it wasn’t a bad time to think about doing something different.

Friedman loved Park’s idea.

“My mother was an active walker,” Friedman says. “She had a walking group and always had a pedometer with her. And my father worked with augmentative engineering [assistive technology] for the elderly and handicapped. We’d played with accelerometer tech before. So it immediately made sense. We just had to refine it.”

The two left CNET, and in April 2007 they incorporated the startup with Park as CEO and Friedman as chief technology officer. Park and Friedman weren’t trying to build the first step counter—mechanical pedometers date back to the 1960s. They weren’t inventing the first smart activity tracker— BodyMedia, a medical device manufacturer, had in 1999 included accelerometers with other sensors in an armband designed to measure calories burned. And Park and Friedman didn’t get a smart consumer tracker to market first. In 2006, Nike had worked with Apple to launch the Nike+ for runners, a motion-tracking system that required a special shoe and a receiver that plugged into an iPod

Two people stand on a busy sidewalk, one wearing a dark sweater and jeans with arms crossed, the other in a brown checkered shirt and light-colored pants with hands on hips. Fitbit’s founders James Park [left] and Eric Friedman released their first product in 2009, when this photo was taken. Peter DaSilva/The New York Times/Redux

Park wasn’t aware of any of this when he thought about getting fitness out of the living room, but the two quickly did their research and figured out what they did and didn’t want to do.

“We didn’t want to create something expensive, targeted at athletes,” he says. “Or something that was dumb and not connected to software. And we wanted something that could provide social connection, like photo sharing did.”

That something had to be comfortable to wear all day, be easy to use, upload its data seamlessly so the data could be tracked and shared with friends, and rarely need charging. Not an easy combination of requirements.

“It’s one of those things where the simpler you get, the harder it becomes to design something well,” Park says.

The first Fitbit was designed for women

The first design decision was the biggest one. Where on the body did they expect people to put this wearable? They weren’t going to ask people to buy special shoes, like the Nike+, or wear a thick band on their upper arms, like BodyMedia’s tracker.

They hired NewDealDesign to figure out some of these details.

“In our first two weeks, after multiple discussions with Eric and James, we decided that the project was going to be geared to women,” says Gadi Amit, president and principal designer of NewDealDesign. “That decision was the driver of the form factor.”

“We wanted to start with something familiar to people,” Park says, “and people tended to clip pedometers to their belts.” So a clip-on device made sense. But women generally don’t wear belts.

To do what it needed to do, the clip-on gadget would have to contain a roughly 2.5-by-2.5-centimeter (1-by-1-inch) printed circuit board, Amit recalls. The big breakthrough came when the team decided to separate the electronics and the battery, which in most devices are stacked. “By doing that, and elongating it a bit, we found that women could put it anywhere,” Amit says. “Many would put it in their bras, so we targeted the design to fit a bra in the center front, purchasing dozens of bras for testing.”

The decision to design for women also drove the overall look, to “subdue the user interface,” as Amit puts it. They hid a low-resolution monochrome OLED display behind a continuous plastic cover, with the display lighting up only when you asked it to. This choice helped give the device an impressive battery life.

A black rectangular object displaying a small blue flower and clipped onto light blue fabric The earliest Fitbit devices used an animated flower as a progress indicator. NewDealDesign

They also came up with the idea of a flower as a progress indicator—inspired, Park says, by the Tamagotchi, one of the biggest toy fads of the late 1990s. “So we had a little animated flower that would shrink or grow based on how active you were,” Park explains.

And after much discussion over controls, the group gave the original Fitbit just one button.

Hiring an EE—from Dad—to design Fitbit’s circuitry

Park and Friedman knew enough about electronics to build a crude prototype, “stuffing electronics into a box made of cut-up balsam wood,” Park says. But they also knew that they needed to bring in a real electrical engineer to develop the hardware.

Fortunately, they knew just whom to call. Friedman’s father, Mark, had for years been working to develop a device for use in nursing homes, to remotely monitor the position of bed-bound patients. Mark’s partner in this effort was Randy Casciola, an electronics engineer and currently president of Morewood Design Labs.

Eric called his dad, told him about the gadget he and Park envisioned, and asked if he and Casciola could build a prototype.

“Mark and I thought we’d build a quick-and-dirty prototype, something they could get sensor data from and use for developing software. And then they’d go off to Asia and get it miniaturized there,” Casciola recalls. “But one revision led to another.” Casciola ended up working on circuit designs for Fitbits virtually full time until the sale of the company to Google, announced in 2019 and completed in early 2021.

“We saw some pretty scary manufacturers. Dirty facilities, flash marks on their injection-molded plastics, very low precision.”
—James Park

“We were just two little guys in a little office in Pittsburgh,” Casciola says. “Before Fitbit came along, we had realized that our nursing-home thing wasn’t likely to ever be a product and had started taking on some consulting work. I had no idea Fitbit would become a household name. I just like working on anything, whether I think it’s a good idea or not, or even whether someone is paying me or not.”

The earliest prototypes were pretty large, about 10 by 15 cm, Casciola says. They were big enough to easily hook up to test equipment, yet small enough to strap on to a willing test subject.

After that, Park and Eric Friedman—along with Casciola, two contracted software engineers, and a mechanical design firm—struggled with turning the bulky prototype into a small and sleek device that counted steps, stored data until it could be uploaded and then transmitted it seamlessly, had a simple user interface, and didn’t need daily charging.

“Figuring out the right balance of battery life, size, and capability kept us occupied for about a year,” Park says.

A black Fitbit sits vertically in a square stand with a wire coming out. The screen on the device reads \u201cBATT 6%\u201d The Fitbit prototype, sitting on its charger, booted up for the first time in December 2008. James Park

After deciding to include a radio transmitter, they made a big move: They turned away from the Bluetooth standard for wireless communications in favor of the ANT protocol, a technology developed by Garmin that used far less power. That meant the Fitbit wouldn’t be able to upload to computers directly. Instead, the team designed their own base station, which could be left plugged into a computer and would grab data anytime the Fitbit wearer passed within range.

Casciola didn’t have expertise in radio-frequency engineering, so he relied on the supplier of the ANT radio chips: Nordic Semiconductor, in Trondheim, Norway.

“They would do a design review of the circuit board layout,” he explains. “Then we would send our hardware to Norway. They would do RF measurements on it and tell me how to tweak the values of the capacitors and conductors in the RF chain, and I would update the schematic. It’s half engineering and half black magic to get this RF stuff working.”

Another standard they didn’t use was the ubiquitous USB charging connection.

“We couldn’t use USB,” Park says. “It just took up too much volume. Somebody actually said to us, ‘Whatever you do, don’t design a custom charging system because it’ll be a pain, it’ll be super expensive.’ But we went ahead and built one. And it was a pain and super expensive, but I think it added a level of magic. You just plopped your device on [the charger]. It looked beautiful, and it worked consistently.”

Most of the electronics they used were off the shelf, including a 16-bit Texas Instruments MSP430 microprocessor, and 92 kilobytes of flash memory and 4 kb of RAM to hold the operating system, the rest of the code, all the graphics, and at least seven days’ worth of collected data.

The Fitbit was designed to resist sweat, and they generally survived showers and quick dips, says Friedman. “But hot tubs were the bane of our existence. People clipped it to their swimsuits and forgot they had it on when they jumped into the hot tub.”

Fitbit’s demo or die moment

Up to this point, the company was surviving on $400,000 invested by Park, Friedman, and a few people who had backed their previous company. But more money would be needed to ramp up manufacturing. And so a critical next step would be a live public demo, which they scheduled for the TechCrunch conference in San Francisco in September 2008.

Live demonstrations of new technologies are always risky, and this one walked right up to the edge of disaster. The plan was to ask an audience member to call out a number, and then Park, wearing the prototype in its balsa-wood box, would walk that number of steps. The count would sync wirelessly to a laptop projecting to a screen on stage. When Friedman hit refresh on the browser, the step count would appear on the screen. What could go wrong?

A lot. Friedman explains: “You think counting steps is easy, but let’s say you do three steps. One, two, three. When you bring your feet together, is that a step or is that the end? It’s much easier to count 1,000 steps than it is to do 10 steps. If I walk 10 steps and am off by one, that’s a glaring error. With 1,000, that variance becomes noise.”

The first semi-assembled Fitbit records its inaugural step count. James Park

After a lot of practice, the two thought they could pull it off. Then came the demo. “While I was walking, the laptop crashed,” Park says. “I wasn’t aware of that. I was just walking happily. Eric had to reboot everything while I was still walking. But the numbers showed up; I don’t think anyone except Eric realized what had happened.”

That day, some 2,000 preorders poured in. And Fitbit closed a $2 million round of venture investment the next month.

Though Park and Friedman had hoped to get Fitbits into users’ hands—or clipped onto their bras—by Christmas of 2008, they missed that deadline by a year.

The algorithms that determine Fitbit’s count

Part of Fitbit’s challenge of getting from prototype to shippable product was software development. They couldn’t expect users to walk as precisely as Park did for the demo. Instead, the device’s algorithms needed to determine what a step was and what was a different kind of motion—say, someone scratching their nose.

“Data collection was difficult,” Park says. “Initially, it was a lot of us wearing prototype devices doing a variety of different activities. Our head of research, Shelten Yuen, would follow, videotaping so we could go back and count the exact number of steps taken. We would wear multiple devices simultaneously, to compare the data collects against each other.”

Friedman remembers one such outing. “James was tethered to the computer, and he was pretending to walk his dog around the Haight [in San Francisco], narrating this little play that he’s putting on: ‘OK, I’m going to stop. The dog is going to pee on this tree. And now he’s going over there.’ The great thing about San Francisco is that nobody looks strangely at two guys tethered together walking around talking to themselves.”

“Older people tend to have an irregular cadence—to the device, older people look a lot like buses going over potholes.” –James Park

“Pushing baby strollers was an issue,” because the wearer’s arms aren’t swinging, Park says. “So one of our guys put an ET doll in a baby stroller and walked all over the city with it.”

Road noise was another big issue. “Yuen, who was working on the algorithms, was based in Cambridge, Mass.,” Park says. “They have more potholes than we do. When he took the bus, the bus would hit the potholes and [the device would] be bouncing along, registering steps.” They couldn’t just fix the issue by looking for a regular cadence to count steps, he adds, because not everyone has a regular cadence. “Older people tend to have an irregular cadence—to the device, older people look a lot like buses going over potholes.”

Fitbit’s founders enter the world of manufacturing

A consumer gadget means mass manufacturing, potentially in huge quantities. They talked to a lot of contract-manufacturing firms, Park recalls. They realized that as a startup with an unclear future market, they wouldn’t be of interest to the top tier of manufacturers. But they couldn’t go with the lowest-budget operations, because they needed a reasonable level of quality.

“We saw some pretty scary manufacturers,” Park said. “Dirty facilities, flash marks on their injection-molded plastics [a sign of a bad seal or other errors], very low precision.” They eventually found a small manufacturer that was “pretty good but still hungry for business.” The manufacturer was headquartered in Singapore, while their surface-mount supplier, which put components directly onto printed circuit boards, was in Batam, Indonesia.

Two rows of women wearing light blue shirts stand at long tables assembling devices. Workers assemble Fitbits by hand in October of 2008. James Park

Working with that manufacturer, Park and Friedman made some tweaks in the design of the circuitry and the shape of the case. They struggled over how to keep water—and sweat—out of the device, settling on ultrasonic welding for the case and adding a spray-on coating for the circuitry after some devices were returned with corrosion on the electronics. That required tweaking the layout to make sure the coating would get between the chips. The coating on each circuit board had to be checked and touched up by hand. When they realized that the coating increased the height of the chips, they had to tweak the layout some more.

In December 2009, just a week before the ship date, Fitbits began rolling off the production line.

“I was in a hotel room in Singapore testing one of the first fully integrated devices,” Park says. “And it wasn’t syncing to my computer. Then I put the device right next to the base station, and it started to sync. Okay, that’s good, but what was the maximum distance it could sync? And that turned out to be literally just a few inches. In every other test we had done, it was fine. It could sync from 15 or 20 feet [5 or 6 meters] away.”

The problem, Park eventually figured out, occurred when the two halves of the Fitbit case were ultrasonically welded together. In previous syncing tests, the cases had been left unsealed. The sealing process pushed the halves closer together, so that the cable for the display touched or nearly touched the antenna printed on the circuit board, which affected the radio signal. Park tried squeezing the halves together on an unsealed unit and reproduced the problem.

Two photos. One photo shows 3 men working in a lab wearing cleanroom suits. One man is seated and handling electronic components, and the others stand observing. The other photo shows a row of six black rectangular devices with green circuit boards hanging out of them Getting the first generation of Fitbits into mass production required some last-minute troubleshooting. Fitbit cofounder James Park [top, standing in center] helps debug a device at the manufacturer shortly before the product’s 2009 launch. Early units from the production line are shown partially assembled [bottom]. James Park

“I thought, if we could just push that cable away from the antenna, we’d be okay,” Park said. “The only thing I could find in my hotel room to do that was toilet paper. So I rolled up some toilet paper really tight and shoved it in between the cable and the antenna. That seemed to work, though I wasn’t really confident.”

Park went to the factory the next day to discuss the problem—and his solution—with the manufacturing team. They refined his fix—replacing the toilet paper with a tiny slice of foam—and that’s how the first generation of Fitbits shipped.

Fitbit’s fast evolution

The company sold about 5,000 of those $99 first-generation units in 2009, and more than 10 times that number in 2010. The rollout wasn’t entirely smooth. Casciola recalls that Fitbit’s logistics center was sending him a surprising number of corroded devices that had been returned by customers. Casciola’s task was to tear them down and diagnose the problem.

“One of the contacts on the device, over time, was growing a green corrosion,” Casciola says. “But the other two contacts were not.” It turned out the problem came from Casciola’s design of the system-reset trigger, which allowed users to reset the device without a reset button or a removable battery. “Inevitably,” Casciola says, “firmware is going to crash. When you can’t take the battery out, you have to have another way of forcing a reset; you don’t want to have someone waiting six days for the battery to run out before restarting.”

The reset that Casciola designed was “a button on the charging station that you could poke with a paper clip. If you did this with the tracker sitting on the charger, it would reset. Of course, we had to have a way for the tracker to see that signal. When I designed the circuit to allow for that, I ended up with a nominal voltage on one pin.” This low voltage was causing the corrosion.

“If you clipped the tracker onto sweaty clothing—remember, sweat has a high salt content—a very tiny current would flow,” says Casciola. “It was just fractions of a microamp, not enough to cause a reset, but enough, over time, to cause greenish corrosion.”

Two men in white cleanroom suits with hoods stand in front of a door. Cofounders Eric Friedman [left] and James Park visit Fitbit’s manufacturer in December of 2008. James Park

On the 2012 generation of the Fitbit, called the Fitbit One, Casciola added a new type of chip, one that hadn’t been available when he was working on the original design. It allowed the single button to trigger a reset when it was held down for some seconds while the device was sitting on the charger. That eliminated the need for the active pin.

The charging interface was the source of another early problem. In the initial design, the trim of the Fitbit’s plastic casing was painted with chrome. “We originally wanted an actual metal trim,” Friedman says, “but that interfered with the radio signal.”

Chrome wasn’t a great choice either. “It caused problems with the charger interface,” Park adds. “We had to do a lot of work to prevent shorting there.”

They dropped the chrome after some tens of thousands of units were shipped—and then got compliments from purchasers about the new, chrome-less look.

Evolution happened quickly, particularly in the way the device transmitted data. In 2012, when Bluetooth LE became widely available as a new low-power communications standard, the base station was replaced by a small Bluetooth communications dongle. And eventually the dongles disappeared altogether.

“We had a huge debate about whether or not to keep shipping that dongle,” Park says. “Its cost was significant, and if you had a recent iPhone, you didn’t need it. But we didn’t want someone buying the device and then returning it because their cellphone couldn’t connect.” The team closely tracked the penetration rate of Bluetooth LE in cellphones; when they felt that number was high enough, they killed off the dongle.

Fitbit’s wrist-ward migration

After several iterations of the original Fitbit design, sometimes called the “clip” for its shape, the fitness tracker moved to the wrist. This wasn’t a matter of simply redesigning the way the device attached to the body but a rethinking of algorithms.

The impetus came from some users’ desire to better track their sleep. The Fitbit’s algorithms allowed it to identify sleep patterns, a design choice that, Park says, “was pivotal, because it changed the device from being just an activity tracker to an all-day wellness tracker.” But nightclothes didn’t offer obvious spots for attachment. So the Fitbit shipped with a thin fabric wristband intended for use just at night. Users began asking customer support if they could keep the wristband on around the clock. The answer was no; Fitbit’s step-counting algorithms at the time didn’t support that.

“My father, who turned 80 on July 5, is fixated on his step count. From 11 at night until midnight, he’s in the parking garage, going up flights of stairs. And he is in better shape than I ever remember him.” —Eric Friedman

Meanwhile, a cultural phenomenon was underway. In the mid-2000s, yellow Livestrong bracelets, made out of silicone and sold to support cancer research, were suddenly everywhere. Other causes and movements jumped on the trend with their own brightly colored wristbands. By early 2013, Fitbit and its competitors Nike and Jawbone had launched wrist-worn fitness trackers in roughly the same style as those trendy bracelets. Fitbit’s version was called the Flex, once again designed by NewDealDesign.

A no-button user interface for the Fitbit Flex

The Flex’s interface was even simpler than the original Fitbit’s one button and OLED screen: It had no buttons and no screen, just five LEDs arranged in a row and a vibrating motor. To change modes, you tapped on the surface.

“We didn’t want to replace people’s watches,” Park says. The technology wasn’t yet ready to “build a compelling device—one that had a big screen and the compute power to drive really amazing interactions on the wrist that would be worthy of that screen. The technology trends didn’t converge to make that possible until 2014 or 2015.”

A photo shows a hand wearing a light blue Fitbit Flex reaching toward a tablet displaying the Fitbit app. Another photo shows a black Fitbit Flex. The Fitbit Flex [right], the first Fitbit designed to be worn on the wrist, was released in 2013. It had no buttons and no screen. Users controlled it by tapping; five LEDs indicated progress toward a step count selected via an app [left]. iStock

“The amount of stuff the team was able to convey with just the LEDs was amazing,” Friedman recalls. “The status of where you are towards reaching your [step] goal, that’s obvious. But [also] the lights cycling to show that it’s searching for something, the vibrating when you hit your step goal, things like that.”

The tap part of the interface, though, was “possibly something we didn’t get entirely right,” Park concedes. It took much fine-tuning of algorithms after the launch to better sort out what was not tapping—like applauding. Even more important, some users couldn’t quite intuit the right way to tap.

“If it works for 98 percent of your users, but you’re growing to millions of users, 2 percent really starts adding up,” Park says. They brought the button back for the next generation of Fitbit devices.

And the rest is history

In 2010, its first full year on the market, the Fitbit sold some 50,000 units. Fitbit sales peaked in 2015, with almost 23 million devices sold that year, according to Statista. Since then, there’s been a bit of a drop-off, as multifunctional smart watches have come down in price and grown in popularity and Fitbit knockoffs entered the market. In 2021, Fitbit still boasted more than 31 million active users, according to Market.us.Media. And Fitbit may now be riding the trend back to simplicity, as people find themselves wanting to get rid of distractions and move back to simpler devices. I see this happening in my own family: My smartwatch-wearing daughter traded in that wearable for a Fitbit Charge 6 earlier this year.

Related Articles


My First Fitbit

The Consumer Electronics Hall of Fame: Fitbit

Fitbit went public in 2015 at a valuation of $4.1 billion. In 2021 Google completed its $2.1 billion purchase of the company and absorbed it into its hardware division. In April of this year, Park and Friedman left Google. Early retirement? Hardly. The two, now age 47, have started a new company that’s currently in stealth mode.

The idea of encouraging people to be active by electronically tracking steps has had staying power.

“My father, who turned 80 on July 5, is fixated on his step count,” Friedman says. “From 11 at night until midnight, he’s in the parking garage, going up flights of stairs. And he is in better shape than I ever remember him.”

What could be a better reward than that?

This article appears in the September 2024 print issue.

  • ✇Ars Technica - All content
  • How accurate are wearable fitness trackers? Less than you might thinkThe Conversation
    Enlarge (credit: Corey Gaskin) Back in 2010, Gary Wolf, then the editor of Wired magazine, delivered a TED talk in Cannes called “the quantified self.” It was about what he termed a “new fad” among tech enthusiasts. These early adopters were using gadgets to monitor everything from their physiological data to their mood and even the number of nappies their children used. Wolf acknowledged that these people were outliers—tech geeks fascinated by data—but their behavior has sin
     

How accurate are wearable fitness trackers? Less than you might think

20. Srpen 2024 v 20:49
How accurate are wearable fitness trackers? Less than you might think

Enlarge (credit: Corey Gaskin)

Back in 2010, Gary Wolf, then the editor of Wired magazine, delivered a TED talk in Cannes called “the quantified self.” It was about what he termed a “new fad” among tech enthusiasts. These early adopters were using gadgets to monitor everything from their physiological data to their mood and even the number of nappies their children used.

Wolf acknowledged that these people were outliers—tech geeks fascinated by data—but their behavior has since permeated mainstream culture.

From the smartwatches that track our steps and heart rate, to the fitness bands that log sleep patterns and calories burned, these gadgets are now ubiquitous. Their popularity is emblematic of a modern obsession with quantification—the idea that if something isn’t logged, it doesn’t count.

Read 18 remaining paragraphs | Comments

  • ✇Pocketables
  • Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangersPaul E King
    The Invoxia GPS Tracker pro is a small rechargeable tracker that works up to three months between charges over cell towers to pinpoint an item’s location. In the event of loss or theft of a vehicle that is being tracked they’ve included a scannable data sheet that an authority can scan and have details of the vehicle currently being tracked. The connection to the cellular network is a subscription, so there is an ongoing cost but unlike a Bluetooth tracker this will work and report in whe
     

Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangers

26. Červen 2024 v 17:15

The Invoxia GPS Tracker pro is a small rechargeable tracker that works up to three months between charges over cell towers to pinpoint an item’s location. In the event of loss or theft of a vehicle that is being tracked they’ve included a scannable data sheet that an authority can scan and have details of the vehicle currently being tracked.

Invoxia GPS Tracker Pro

The connection to the cellular network is a subscription, so there is an ongoing cost but unlike a Bluetooth tracker this will work and report in whether there are iPhones or Androids nearby. The location update frequency can be cranked up to every 30 seconds in the event the object being tracked is actively moving, or the GPS can phone in any time it detects it’s being moved and you’ll have a device that lasts several months on a charge.

Alternately you can simply attach it to a USB in your trunk, or off of your motorcycle battery (some equipment required) and never think about power again.

While there is an around $9 a month charge for the LTE connectivity, the question becomes how much is what you’re tracking worth? Bluetooth trackers work on the kindness of nearby phone strangers, and simply getting a stolen vehicle off the beaten path can defeat them. With an LTE tracker you have to go a bit further and locate an area with no cell towers, or have a quite detectable and illegal cell phone jammer.

The base GPS Tracker Pro is $99 and the monthly service is $8.95 a month or $6.25 a month prepaid/long term (according to Amazon product description)

Invoxia GPS Tracker Pro stock image

There’s a proximity radar in the app for when you’re in Bluetooth range to make the unit beep and find it so if you’re close it can get you closer.

You can configure alerts for movement, which I believe would be extremely useful if you’ve got this in a motorcycle and are not on said motorcycle. I will never forget informing a new rider that if you park a bike outside overnight the bike faeries come and escort the bike away. The only issue with the Invoxia GPS Tracker Pro is it’s large enough to be easily spotted in a bike’s trunk.

Nitpicking the Invoxia GPS Tracker Pro

The first thing that comes to mind with this is the theft report form – this is something that’s mailed to a police officer most likely and allows the officer to see via QR code where the tracker is currently reporting it is. Most notably missing useful information here is vehicle identification number, color, perhaps a picture of the vehicle, and contact information beyond name and email.

Thieves swap plates, but they’re probably not going to paint the vehicle and disguise the VIN

Invoxia GPS Tracker Pro theft report

It’s a good start, but they need to talk to a police officer or someone who’s ever had their vehicle stolen.

The next thing in a similar vein is that the tracker is portable and you can swap it between vehicles or maybe just throw it in a bag for travel. I’d assume the ability to switch what you’re reporting stolen on the fly might be useful.

Next – it’s 2024, use USB-C already… the Invoxia GPS Tracker Pro has a Micro-USB connection. Come on man. A whole continent told Apple to get with the program due to cable waste already. No more Micro-USB.

There is no option to update more frequently when plugged in. This makes tracking a delivery driver less useful as they may make a stop, deliver an item, and be off before the tracker updates. If you’re paying the cell company charge for service, might as well utilize it when the device has an external power source.

And finally – for a brief time on the Invoxia website, this page in particular, there existed an article that I am told was for the wrong device. They have since removed this at my noticing, but it indicated you could send a help cry by pressing a button. Unfortunately the button is only for resetting the device, but it does seem that the software could be easily modified to report to the app when the tracker had rebooted as a backup emergency button.

Wrap-up

While I have done some nitpicking, overall this works well for a movable rechargeable tracker that stands alone. The app needs a little work, but it’s quite close to being everything I think it needs to be and I suspect they will keep working on it as long as people keep purchasing their products.

The Invoxia GPS Tracker Pro is available on Invoxia’s website and Amazon. The Amazon link is a tagged link, should you not want us to make a commission on sales just go to Amazon and search for it yourself.

GPS Tracker Pro
image 4 - for some reason we don't have an alt tag here

The Invoxia GPS Tracker Pro is a LTE-enabled tracker that does not rely on a network of strangers to locate your tracker, just a cell signal.

Product Brand: Invoxia

Product Currency: USD

Product Price: 69.95

Product In-Stock: InStock

Editor's Rating:
4

Pros

  • LTE based
  • In emergency mode can report location at 30 second intervals
  • Rechargeable

Cons

  • Cell service required
  • Software needs some work

Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangers by Paul E King first appeared on Pocketables.

  • ✇Pocketables
  • Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangersPaul E King
    The Invoxia GPS Tracker pro is a small rechargeable tracker that works up to three months between charges over cell towers to pinpoint an item’s location. In the event of loss or theft of a vehicle that is being tracked they’ve included a scannable data sheet that an authority can scan and have details of the vehicle currently being tracked. The connection to the cellular network is a subscription, so there is an ongoing cost but unlike a Bluetooth tracker this will work and report in whe
     

Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangers

26. Červen 2024 v 17:15

The Invoxia GPS Tracker pro is a small rechargeable tracker that works up to three months between charges over cell towers to pinpoint an item’s location. In the event of loss or theft of a vehicle that is being tracked they’ve included a scannable data sheet that an authority can scan and have details of the vehicle currently being tracked.

Invoxia GPS Tracker Pro

The connection to the cellular network is a subscription, so there is an ongoing cost but unlike a Bluetooth tracker this will work and report in whether there are iPhones or Androids nearby. The location update frequency can be cranked up to every 30 seconds in the event the object being tracked is actively moving, or the GPS can phone in any time it detects it’s being moved and you’ll have a device that lasts several months on a charge.

Alternately you can simply attach it to a USB in your trunk, or off of your motorcycle battery (some equipment required) and never think about power again.

While there is an around $9 a month charge for the LTE connectivity, the question becomes how much is what you’re tracking worth? Bluetooth trackers work on the kindness of nearby phone strangers, and simply getting a stolen vehicle off the beaten path can defeat them. With an LTE tracker you have to go a bit further and locate an area with no cell towers, or have a quite detectable and illegal cell phone jammer.

The base GPS Tracker Pro is $99 and the monthly service is $8.95 a month or $6.25 a month prepaid/long term (according to Amazon product description)

Invoxia GPS Tracker Pro stock image

There’s a proximity radar in the app for when you’re in Bluetooth range to make the unit beep and find it so if you’re close it can get you closer.

You can configure alerts for movement, which I believe would be extremely useful if you’ve got this in a motorcycle and are not on said motorcycle. I will never forget informing a new rider that if you park a bike outside overnight the bike faeries come and escort the bike away. The only issue with the Invoxia GPS Tracker Pro is it’s large enough to be easily spotted in a bike’s trunk.

Nitpicking the Invoxia GPS Tracker Pro

The first thing that comes to mind with this is the theft report form – this is something that’s mailed to a police officer most likely and allows the officer to see via QR code where the tracker is currently reporting it is. Most notably missing useful information here is vehicle identification number, color, perhaps a picture of the vehicle, and contact information beyond name and email.

Thieves swap plates, but they’re probably not going to paint the vehicle and disguise the VIN

Invoxia GPS Tracker Pro theft report

It’s a good start, but they need to talk to a police officer or someone who’s ever had their vehicle stolen.

The next thing in a similar vein is that the tracker is portable and you can swap it between vehicles or maybe just throw it in a bag for travel. I’d assume the ability to switch what you’re reporting stolen on the fly might be useful.

Next – it’s 2024, use USB-C already… the Invoxia GPS Tracker Pro has a Micro-USB connection. Come on man. A whole continent told Apple to get with the program due to cable waste already. No more Micro-USB.

There is no option to update more frequently when plugged in. This makes tracking a delivery driver less useful as they may make a stop, deliver an item, and be off before the tracker updates. If you’re paying the cell company charge for service, might as well utilize it when the device has an external power source.

And finally – for a brief time on the Invoxia website, this page in particular, there existed an article that I am told was for the wrong device. They have since removed this at my noticing, but it indicated you could send a help cry by pressing a button. Unfortunately the button is only for resetting the device, but it does seem that the software could be easily modified to report to the app when the tracker had rebooted as a backup emergency button.

Wrap-up

While I have done some nitpicking, overall this works well for a movable rechargeable tracker that stands alone. The app needs a little work, but it’s quite close to being everything I think it needs to be and I suspect they will keep working on it as long as people keep purchasing their products.

The Invoxia GPS Tracker Pro is available on Invoxia’s website and Amazon. The Amazon link is a tagged link, should you not want us to make a commission on sales just go to Amazon and search for it yourself.

GPS Tracker Pro
image 4 - for some reason we don't have an alt tag here

The Invoxia GPS Tracker Pro is a LTE-enabled tracker that does not rely on a network of strangers to locate your tracker, just a cell signal.

Product Brand: Invoxia

Product Currency: USD

Product Price: 69.95

Product In-Stock: InStock

Editor's Rating:
4

Pros

  • LTE based
  • In emergency mode can report location at 30 second intervals
  • Rechargeable

Cons

  • Cell service required
  • Software needs some work

Invoxia GPS Tracker Pro – a small lightweight tracker that doesn’t rely on a network of strangers by Paul E King first appeared on Pocketables.

Lilbits: Intel’s 13th and 14th-gen desktop chip issues, AMD’s Ryzen AI 300 arrives, and a $56 Casio watch that’s also a (basic) fitness tracker

29. Červenec 2024 v 22:37

Over the past year or two there have been a growing number of complaints that some 13th and 14th-gen Intel Core chips for desktop computers were crash-prone and generally unstable. Now Intel has confirmed the issue is real, promised to roll out a microcode update that will prevent it from happening on chip that haven’t […]

The post Lilbits: Intel’s 13th and 14th-gen desktop chip issues, AMD’s Ryzen AI 300 arrives, and a $56 Casio watch that’s also a (basic) fitness tracker appeared first on Liliputing.

  • ✇IEEE Spectrum
  • Apps Put a Psychiatrist in Your PocketGwendolyn Rak
    Nearly every day since she was a child, Alex Leow, a psychiatrist and computer scientist at the University of Illinois Chicago, has played the piano. Some days she plays well, and other days her tempo lags and her fingers hit the wrong keys. Over the years, she noticed a pattern: How well she plays depends on her mood. A bad mood or lack of sleep almost always leads to sluggish, mistake-prone music. In 2015, Leow realized that a similar pattern might be true for typing. She wondered if she co
     

Apps Put a Psychiatrist in Your Pocket

19. Květen 2024 v 17:00


Nearly every day since she was a child, Alex Leow, a psychiatrist and computer scientist at the University of Illinois Chicago, has played the piano. Some days she plays well, and other days her tempo lags and her fingers hit the wrong keys. Over the years, she noticed a pattern: How well she plays depends on her mood. A bad mood or lack of sleep almost always leads to sluggish, mistake-prone music.

In 2015, Leow realized that a similar pattern might be true for typing. She wondered if she could help people with psychiatric conditions track their moods by collecting data about their typing style from their phones. She decided to turn her idea into an app.

After conducting a pilot study, in 2018 Leow launched BiAffect, a research app that aims to understand mood-related symptoms of bipolar disorder through keyboard dynamics and sensor data from users’ smartphones. Now in use by more than 2,700 people who have volunteered their data to the project, the app tracks typing speed and accuracy by swapping the phone’s onscreen keyboard with its own nearly identical one.

The software then generates feedback for users, such as a graph displaying hourly keyboard activity. Researchers get access to the donated data from users’ phones, which they use to develop and test machine learning algorithms that interpret data for clinical use. One of the things Leow’s team has observed: When people are manic—a state of being overly excited that accompanies bipolar disorder—they type “ferociously fast,” says Leow.

Three screenshots of BiAffects app show a healthy patient, with a range of time spent lying down, a bipolar patient with little time spent prone, and one with depression and significant time spent lying down. Compared to a healthy user [top], a person experiencing symptoms of bipolar disorder [middle] or depression [bottom] may use their phone more than usual and late at night. BiAffect measures phone usage and orientation to help track those symptoms. BiAffect

BiAffect is one of the few mental-health apps that take a passive approach to collecting data from a phone to make inferences about users’ mental states. (Leow suspects that fewer than a dozen are currently available to consumers.) These apps run in the background on smartphones, collecting different sets of data not only on typing but also on the user’s movements, screen time, call and text frequency, and GPS location to monitor social activity and sleep patterns. If an app detects an abrupt change in behavior, indicating a potentially hazardous shift in mental state, it could be set up to alert the user, a caretaker, or a physician.

Such apps can’t legally claim to treat or diagnose disease, at least in the United States. Nevertheless, many researchers and people with mental illness have been using them as tools to track signs of depression, schizophrenia, anxiety, and bipolar disorder. “There’s tremendous, immediate clinical value in helping people feel better today by integrating these signals into mental-health care,” says John Torous, director of digital psychiatry at Beth Israel Deaconess Medical Center, in Boston. Globally, one in 8 people live with a mental illness, including 40 million with bipolar disorder.

These apps differ from most of the more than 10,000 mental-health and mood apps available, which typically ask users to actively log how they’re feeling, help users connect to providers, or encourage mindfulness. The popular apps Daylio and Moodnotes, for example, require journaling or rating symptoms. This approach requires more of the user’s time and may make these apps less appealing for long-term use. A 2019 study found that among 22 mood-tracking apps, the median user-retention rate was just 6.1 percent at 30 days of use.

App developers are trying to avoid the pitfalls of previous smartphone-psychiatry startups, some of which oversold their capabilities before validating their technologies.

But despite years of research on passive mental-health apps, their success is far from guaranteed. App developers are trying to avoid the pitfalls of previous smartphone psychiatry startups, some of which oversold their capabilities before validating their technologies. For example, Mindstrong was an early startup with an app that tracked taps, swipes, and keystrokes to identify digital biomarkers of cognitive function. The company raised US $160 million in funding from investors, including $100 million in 2020 alone, and went bankrupt in February 2023.

Mindstrong may have folded because the company was operating on a different timeline from the research, according to an analysis by the health-care news website Stat. The slow, methodical pace of science did not match the startup’s need to return profits to its investors quickly, the report found. Mindstrong also struggled to figure out the marketplace and find enough customers willing to pay for the service. “We were first out of the blocks trying to figure this out,” says Thomas Insel, a psychiatrist who cofounded Mindstrong.

Now that the field has completed a “hype cycle,” Torous says, app developers are focused on conducting the research needed to prove their apps can actually help people. “We’re beginning to put the burden of proof more on those developers and startups, as well as academic teams,” he says. Passive mental-health apps need to prove they can reliably parse the data they’re collecting, while also addressing serious privacy concerns.

Passive sensing catches mood swings early

Mood Sensors

Seven metrics apps use to make inferences about your mood

An illustration of a series of keys.  All icons: Greg Mably

Keyboard dynamics: Typing speed and accuracy can indicate a lot about a person’s mood. For example, people who are manic often type extremely fast.

An illustration of a pair of curved arrows.

Accelerometer: This sensor tracks how the user is oriented and moving. Lying in bed would suggest a different mood than going for a run.

An illustration of a phone and text bubble icon.

Calls and texts: The frequency of text messages and phone conversations signifies a person’s social isolation or activity, which indicates a certain mood.

An illustration of an arrow pointing downward

GPS location: Travel habits signal a person’s activity level and routine, which offer clues about mood. For example, a person experiencing depression may spend more time at home.

An illustration of a speaker and sound coming off

Mic and voice: Mood can affect how a person speaks. Microphone-based sensing tracks the rhythm and inflection of a person’s voice.

An illustration of multicolored

Sleep: Changes in sleep patterns signify a change in mood. Insomnia is a common symptom of bipolar disorder and can trigger or worsen mood disturbances.

An illustration of colored bars.

Screen time: An increase in the amount of time a person spends on a phone can be a sign of depressive symptoms and can interfere with sleep.

A crucial component of managing psychiatric illness is tracking changes in mental states that can lead to more severe episodes of the disease. Bipolar disorder, for example, causes intense swings in mood, from extreme highs during periods of mania to extreme lows during periods of depression. Between 30 and 50 percent of people with bipolar disorder will attempt suicide at least once in their lives. Catching early signs of a mood swing can enable people to take countermeasures or seek help before things get bad.

But detecting those changes early is hard, especially for people with mental illness. Observations by other people, such as family members, can be subjective, and doctor and counselor sessions are too infrequent.

That’s where apps come in. Algorithms can be trained to spot subtle deviations from a person’s normal routine that might indicate a change in mood—an objective measure based on data, like a diabetic tracking blood sugar. “The ability to think objectively about my own thinking is really key,” says retired U.S. major general Gregg Martin, who has bipolar disorder and is an advisor for BiAffect.

The data from passive sensing apps could also be useful to doctors who want to see objective data on their patients in between office visits, or for people transitioning from inpatient to outpatient settings. These apps are “providing a service that doesn’t exist,” says Colin Depp, a clinical psychologist and professor at the University of California, San Diego. Providers can’t observe their patients around the clock, he says, but smartphone data can help close the gap.

Depp and his team have developed an app that uses GPS data and microphone-based sensing to determine the frequency of conversations and make inferences about a person’s social interactions and isolation. The app also tracks “location entropy,” a metric of how much a user moves around outside of routine locations. When someone is depressed and mostly stays home, location entropy decreases.

Depp’s team initially developed the app, called CBT2go, as a way to test the effectiveness of cognitive behavioral therapy in between therapy sessions. The app can now intervene in real time with people experiencing depressive or psychotic symptoms. This feature helps people identify when they feel lonely or agitated so they can apply coping skills they’ve learned in therapy. “When people walk out of the therapist’s office or log off, then they kind of forget all that,” Depp says.

Another passive mental-health-app developer, Ellipsis Health in San Francisco, uses software that takes voice samples collected during telehealth calls to gauge a person’s level of depression, anxiety, and stress symptoms. For each set of symptoms, deep-learning models analyze the person’s words, rhythms, and inflections to generate a score. The scores indicate the severity of the person’s mental distress, and are based on the same scales used in standard clinical evaluations, says Michael Aratow, cofounder and chief medical officer at Ellipsis.

Aratow says the software works for people of all demographics, without needing to first capture baseline measures of an individual’s voice and speech patterns. “We’ve trained the models in the most difficult use cases,” he says. The company offers its platform, including an app for collecting the voice data, through health-care providers, health systems, and employers; it’s not directly available to consumers.

In the case of BiAffect, the app can be downloaded for free by the public. Leow and her team are using the app as a research tool in clinical trials sponsored by the U.S. National Institutes for Health. These studies aim to validate whether the app can reliably monitor mood disorders, and determine whether it could also track suicide risk in menstruating women and cognition in people with multiple sclerosis.

BiAffect’s software tracks behaviors like hitting the backspace key frequently, which suggests more errors, and an increase in typing “@” symbols and hashtags, which suggest more social media use. The app combines this typing data with information from the phone’s accelerometer to determine how the user is oriented and moving—for example, whether the user is likely lying down in bed—which yields more clues about mood.

Screenshot of Ellipsis Health sample patient\u2019s case management dashboard with text about the patient\u2019s health and popup window showing high risk score Ellipsis Health analyzes audio captured during telehealth visits to assign scores for depression, anxiety, and stress.Ellipsis Health

The makers of BiAffect and Ellipsis Health don’t claim their apps can treat or diagnose disease. If app developers want to make those claims and sell their product in the United States, they would first have to get regulatory approval from the U.S. Food and Drug Administration. Getting that approval requires rigorous and large-scale clinical trials that most app makers don’t have the resources to conduct.

Digital-health software depends on quality clinical data

The sensing techniques upon which passive apps rely—measuring typing dynamics, movement, voice acoustics, and the like—are well established. But the algorithms used to analyze the data collected by the sensors are still being honed and validated. That process will require considerably more high-quality research among real patient populations.

Illustration of a hand holding a phone upwards, with many colored bubbles floating around them. Greg Mably

For example, clinical studies that include control or placebo groups are crucial and have been lacking in the past. Without control groups, companies can say their technology is effective “compared to nothing,” says Torous at Beth Israel.

Torous and his team aim to build software that is backed by this kind of quality evidence. With participants’ consent, their app, called mindLAMP, passively collects data from their screen time and their phone’s GPS and accelerometer for research use. It’s also customizable for different diseases, including schizophrenia and bipolar disorder. “It’s a great starting point. But to bring it into the medical context, there’s a lot of important steps that we’re now in the middle of,” says Torous. Those steps include conducting clinical trials with control groups and testing the technology in different patient populations, he says.

How the data is collected can make a big difference in the quality of the research. For example, the rate of sampling—how often a data point is collected—matters and must be calibrated for the behavior being studied. What’s more, data pulled from real-world environments tends to be “dirty,” with inaccuracies collected by faulty sensors or inconsistencies in how phone sensors initially process data. It takes more work to make sense of this data, says Casey Bennett, an assistant professor and chair of health informatics at DePaul University, in Chicago, who uses BiAffect data in his research.

One approach to addressing errors is to integrate multiple sources of data to fill in the gaps—like combining accelerometer and typing data. In another approach, the BiAffect team is working to correlate real-world information with cleaner lab data collected in a controlled environment where researchers can more easily tell when errors are introduced.

Who participates in the studies matters too. If participants are limited to a particular geographic area or demographic, it’s unclear whether the results can be applied to the broader population. For example, a night-shift worker will have different activity patterns from those with nine-to-five jobs, and a city dweller may have a different lifestyle from residents of rural areas.

After the research is done, app developers must figure out a way to integrate their products into real-world medical contexts. One looming question is when and how to intervene when a change in mood is detected. These apps should always be used in concert with a professional and not as a replacement for one, says Torous. Otherwise, the app’s assessments could be dangerous and distressing to users, he says.

When mood tracking feels like surveillance

No matter how well these passive mood-tracking apps work, gaining trust from potential users may be the biggest stumbling block. Mood tracking could easily feel like surveillance. That’s particularly true for people with bipolar or psychotic disorders, where paranoia is part of the illness.

Keris Myrick, a mental-health advocate, says she finds passive mental-health apps “both cool and creepy.” Myrick, who is vice president of partnerships and innovation at the mental-health-advocacy organization Inseparable, has used a range of apps to support her mental health as a person with schizophrenia. But when she tested one passive sensing app, she opted to use a dummy phone. “I didn’t feel safe with an app company having access to all of that information on my personal phone,” Myrick says. While she was curious to see if her subjective experience matched the app’s objective measurements, the creepiness factor prevented her from using the app enough to find out.

Keris Myrick, a mental-health advocate, says she finds passive mental-health apps “both cool and creepy.”

Beyond users’ perception, maintaining true digital privacy is crucial. “Digital footprints are pretty sticky these days,” says Katie Shilton, an associate professor at the University of Maryland focused on social-data science. It’s important to be transparent about who has access to personal information and what they can do with it, she says.

“Once a diagnosis is established, once you are labeled as something, that can affect algorithms in other places in your life,” Shilton says. She cites the misuse of personal data in the Cambridge Analytica scandal, in which the consulting firm collected information from Facebook to target political advertising. Without strong privacy policies, companies producing mental-health apps could similarly sell user data—and they may be particularly motivated to do so if an app is free to use.

Conversations about regulating mental-health apps have been ongoing for over a decade, but a Wild West–style lack of regulation persists in the United States, says Bennett of DePaul University. For example, there aren’t yet protections in place to keep insurance companies or employers from penalizing users based on data collected. “If there aren’t legal protections, somebody is going to take this technology and use it for nefarious purposes,” he says.

Some of these concerns may be mediated by confining all the analysis to a user’s phone, rather than collecting data in a central repository. But decisions about privacy policies and data structures are still up to individual app developers.

Leow and the BiAffect team are currently working on a new internal version of their app that incorporates natural-language processing and generative AI extensions to analyze users’ speech. The team is considering commercializing this new version in the future, but only following extensive work with industry partners to ensure strict privacy safeguards are in place. “I really see this as something that people could eventually use,” Leow says. But she acknowledges that researchers’ goals don’t always align with the desires of the people who might use these tools. “It is so important to think about what the users actually want.”

  • ✇Pocketables
  • Does Android’s unknown tracker alerts work for anyone? (updated)Paul E King
    Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time). Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occ
     

Does Android’s unknown tracker alerts work for anyone? (updated)

24. Duben 2024 v 15:29

Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time).

Results of a manual scan when looking for unknown trackers
Unknown tracker alert screenshot saying there are no tracker alerts currently

Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occasionally to keep the battery juiced and the wheels not dry rotting. She’s in another state, will be back in two to three weeks, no big whoop. I mention this because she is currently separated from her AirTag on her keychain (in my possession,) and a Tile tracker sitting in her car.

I didn’t think anything much about this yesterday as I drove her car around, but then realized today that either both of her trackers have died in one week in my possession, or the tracker finder simply is not working on the current version of Android on my Pixel 8 Pro (yes, it’s turned on). Alternately she left some device in her car which is telling the trackers they’re still connected to the owner.

Checking the documentation on Android’s Unknown Tracker Alerts it lists Apple AirTags by name, and Find My Device network compatible trackers, where Tile is listed as one such.

Initiating a manual scan similarly nets no unknown trackers. Both of these are separated from the owner for over a week, and device they were set up on (presumably her phone) by several hundred miles for a week now. I would suspect I should be getting alerts.

Have you ever gotten an alert? Know any reason why I’m not? Would be interested to know why it’s not working as I drove for at least 50 miles yesterday in that car.

Not attempting to manufacture outrage, really just wondering if anyone has ever seen a warning when traveling with someone else’s trackers separate from the phone they were paired to.

The next day (I don’t write these all at once)

I checked with the owner of the tags who said it’s possible the batteries were shot, and I just so happened to have a pack of CR2032s laying around so I replaced the AirTag battery (which was listing as weak but not dead according to my battery tester,) heard the beep from the AirTag (have not investigated the tile yet) and I drove around yesterday with a functioning AirTag that is not mine sitting in my car waiting for an alert.

It never came.

I manually scanned for unknown trackers, no trackers detected. This was odd as I was right next to it. Went and manually scanned again and Android finally found the AirTag tracker.

I now have the AirTag found from a manual scan, but this does not seem to have ever alerted me that a tracker was around. I drove in with the AirTag today, no alerts… not sure if there will be any due to finding it in a manual scan.

Pixel 8 Pro, current Android revision (April 2024)

Updates

At 19 hours of having the new battery in I was informed a device was traveling with me. Now, whether this is 19 hours or several days (since the last battery did have a charge,) I’d really rather cut that down to a few minutes personally as if someone plants this on my car I don’t really want it sitting broadcasting my location.

2024 04 25 07.31.55 - for some reason we don't have an alt tag here
2024 04 25 07.32.43 - for some reason we don't have an alt tag here
2024 04 25 07.40.35 - for some reason we don't have an alt tag here

The alert (first picture up there) was what I received this morning. The first detected time is probably when the manual scan caught it. That tracker was within 50 feet of me most of the day. Second picture is several miles away from my house where it had pinpointed the tracker. Yeah I’m not doxxing myself.

It feels a bit like someone could slip this on your car at the bar, use it, come and rob you/whatever, and be gone before the tracker alert ever kicked in.

I was able to make the tracker beep and locate it (knowing exactly where it was anyway) but yikes.

Does Android’s unknown tracker alerts work for anyone? (updated) by Paul E King first appeared on Pocketables.

  • ✇Pocketables
  • Does Android’s unknown tracker alerts work for anyone? (updated)Paul E King
    Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time). Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occ
     

Does Android’s unknown tracker alerts work for anyone? (updated)

24. Duben 2024 v 15:29

Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time).

Results of a manual scan when looking for unknown trackers
Unknown tracker alert screenshot saying there are no tracker alerts currently

Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occasionally to keep the battery juiced and the wheels not dry rotting. She’s in another state, will be back in two to three weeks, no big whoop. I mention this because she is currently separated from her AirTag on her keychain (in my possession,) and a Tile tracker sitting in her car.

I didn’t think anything much about this yesterday as I drove her car around, but then realized today that either both of her trackers have died in one week in my possession, or the tracker finder simply is not working on the current version of Android on my Pixel 8 Pro (yes, it’s turned on). Alternately she left some device in her car which is telling the trackers they’re still connected to the owner.

Checking the documentation on Android’s Unknown Tracker Alerts it lists Apple AirTags by name, and Find My Device network compatible trackers, where Tile is listed as one such.

Initiating a manual scan similarly nets no unknown trackers. Both of these are separated from the owner for over a week, and device they were set up on (presumably her phone) by several hundred miles for a week now. I would suspect I should be getting alerts.

Have you ever gotten an alert? Know any reason why I’m not? Would be interested to know why it’s not working as I drove for at least 50 miles yesterday in that car.

Not attempting to manufacture outrage, really just wondering if anyone has ever seen a warning when traveling with someone else’s trackers separate from the phone they were paired to.

The next day (I don’t write these all at once)

I checked with the owner of the tags who said it’s possible the batteries were shot, and I just so happened to have a pack of CR2032s laying around so I replaced the AirTag battery (which was listing as weak but not dead according to my battery tester,) heard the beep from the AirTag (have not investigated the tile yet) and I drove around yesterday with a functioning AirTag that is not mine sitting in my car waiting for an alert.

It never came.

I manually scanned for unknown trackers, no trackers detected. This was odd as I was right next to it. Went and manually scanned again and Android finally found the AirTag tracker.

I now have the AirTag found from a manual scan, but this does not seem to have ever alerted me that a tracker was around. I drove in with the AirTag today, no alerts… not sure if there will be any due to finding it in a manual scan.

Pixel 8 Pro, current Android revision (April 2024)

Updates

At 19 hours of having the new battery in I was informed a device was traveling with me. Now, whether this is 19 hours or several days (since the last battery did have a charge,) I’d really rather cut that down to a few minutes personally as if someone plants this on my car I don’t really want it sitting broadcasting my location.

2024 04 25 07.31.55 - for some reason we don't have an alt tag here
2024 04 25 07.32.43 - for some reason we don't have an alt tag here
2024 04 25 07.40.35 - for some reason we don't have an alt tag here

The alert (first picture up there) was what I received this morning. The first detected time is probably when the manual scan caught it. That tracker was within 50 feet of me most of the day. Second picture is several miles away from my house where it had pinpointed the tracker. Yeah I’m not doxxing myself.

It feels a bit like someone could slip this on your car at the bar, use it, come and rob you/whatever, and be gone before the tracker alert ever kicked in.

I was able to make the tracker beep and locate it (knowing exactly where it was anyway) but yikes.

Does Android’s unknown tracker alerts work for anyone? (updated) by Paul E King first appeared on Pocketables.

  • ✇Pocketables
  • Does Android’s unknown tracker alerts work for anyone? (updated)Paul E King
    Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time). Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occ
     

Does Android’s unknown tracker alerts work for anyone? (updated)

24. Duben 2024 v 15:29

Unknown Tracker Alerts is a feature in Android that will look for Bluetooth trackers and report if any that are separated from their owner are in operation around you. This should tell you when someone has planted a tracker on your car, but should not tell you when Dave walks in with his keychain Tile finder (since it’s not separated from him for any length of time).

Results of a manual scan when looking for unknown trackers
Unknown tracker alert screenshot saying there are no tracker alerts currently

Here’s my story – A friend of mine dropped off her car for a couple of weeks and asked me and my wife to drive it occasionally to keep the battery juiced and the wheels not dry rotting. She’s in another state, will be back in two to three weeks, no big whoop. I mention this because she is currently separated from her AirTag on her keychain (in my possession,) and a Tile tracker sitting in her car.

I didn’t think anything much about this yesterday as I drove her car around, but then realized today that either both of her trackers have died in one week in my possession, or the tracker finder simply is not working on the current version of Android on my Pixel 8 Pro (yes, it’s turned on). Alternately she left some device in her car which is telling the trackers they’re still connected to the owner.

Checking the documentation on Android’s Unknown Tracker Alerts it lists Apple AirTags by name, and Find My Device network compatible trackers, where Tile is listed as one such.

Initiating a manual scan similarly nets no unknown trackers. Both of these are separated from the owner for over a week, and device they were set up on (presumably her phone) by several hundred miles for a week now. I would suspect I should be getting alerts.

Have you ever gotten an alert? Know any reason why I’m not? Would be interested to know why it’s not working as I drove for at least 50 miles yesterday in that car.

Not attempting to manufacture outrage, really just wondering if anyone has ever seen a warning when traveling with someone else’s trackers separate from the phone they were paired to.

The next day (I don’t write these all at once)

I checked with the owner of the tags who said it’s possible the batteries were shot, and I just so happened to have a pack of CR2032s laying around so I replaced the AirTag battery (which was listing as weak but not dead according to my battery tester,) heard the beep from the AirTag (have not investigated the tile yet) and I drove around yesterday with a functioning AirTag that is not mine sitting in my car waiting for an alert.

It never came.

I manually scanned for unknown trackers, no trackers detected. This was odd as I was right next to it. Went and manually scanned again and Android finally found the AirTag tracker.

I now have the AirTag found from a manual scan, but this does not seem to have ever alerted me that a tracker was around. I drove in with the AirTag today, no alerts… not sure if there will be any due to finding it in a manual scan.

Pixel 8 Pro, current Android revision (April 2024)

Updates

At 19 hours of having the new battery in I was informed a device was traveling with me. Now, whether this is 19 hours or several days (since the last battery did have a charge,) I’d really rather cut that down to a few minutes personally as if someone plants this on my car I don’t really want it sitting broadcasting my location.

2024 04 25 07.31.55 - for some reason we don't have an alt tag here
2024 04 25 07.32.43 - for some reason we don't have an alt tag here
2024 04 25 07.40.35 - for some reason we don't have an alt tag here

The alert (first picture up there) was what I received this morning. The first detected time is probably when the manual scan caught it. That tracker was within 50 feet of me most of the day. Second picture is several miles away from my house where it had pinpointed the tracker. Yeah I’m not doxxing myself.

It feels a bit like someone could slip this on your car at the bar, use it, come and rob you/whatever, and be gone before the tracker alert ever kicked in.

I was able to make the tracker beep and locate it (knowing exactly where it was anyway) but yikes.

Does Android’s unknown tracker alerts work for anyone? (updated) by Paul E King first appeared on Pocketables.

Xiaomi Band 9 get certified by multiple agencies – to launch soon

Od: Efe Udin
20. Duben 2024 v 11:42
Xiaomi Band 9

Xiaomi has been a significant player in the budget-friendly fitness tracker market. With the Mi Band series, the company has been offering a wide range ...

The post Xiaomi Band 9 get certified by multiple agencies – to launch soon appeared first on Gizchina.com.

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