Technologies

How to carry your COVID-19 vaccine card on your iPhone or Android phone

You may need proof of vaccination to get into restaurants, bars, theaters and other businesses — but you don’t have to carry that paper card with you.

For the most up-to-date news and information about the coronavirus pandemic, visit the WHO and CDC websites.

Have you received your COVID-19 booster yet? With omicron, will you need a fourth vaccine dose? With vaccine-makers preparing for an omicron-specific booster if the new COVID-19 variantis as serious as some fear, that piece of paper with your vaccine record could get crowded.

With many counties and cities requiring you to show your vaccine card and ID to get into restaurants, bars and theaters (or even your place of work), you’ll need to carry a record of your COVID shots with you if you want to enter. You don’t, however, necessarily have to keep the printed version in your wallet or purse. We recommend storing it in your phone instead to make your life easier by preventing loss or damage. You carry your phone everywhere, right?

Not sure where to start? We’ll tell you all the ways you can store your vaccine card on your phone — including methods to use if you have an Android phone or iPhone, or if your state has a specific app. Be aware that if you get a booster dose, you need to re-upload your vaccine card. For more details about the coronavirus, here’s the latest on long COVID and what to know about mixing your COVID-19 booster shot. This story was recently updated.

Which states are using vaccination record apps?

Many states have apps that let their residents store a digital version of their vaccine cards on their phones, including California, Colorado, Hawaii, New York and Oregon.

Colorado residents, for example, can download the myColorado app. It requires you to create an account, verify your identity and then add your digital driver’s license to your phone. After you’ve done that, you can then add your myVaccine record to the app.

Louisiana’s LA Wallet app takes a similar approach to Colorado’s, allowing you to add your driver’s license and proof of vaccination to your phone.

California’s version requires you to fill out a form to verify your identity, after which you’ll receive a text message or email with a link to a QR code you can save to your phone. When scanned, the code will offer proof of vaccination. The link will also include a digital copy of your vaccination record.

Illinois residents can use VaxVerify to show proof. The app uses Experian for identity verification.

MyIR Mobile is another app used by several state health departments to provide a digital copy of your vaccination card. Currently, if you live in Louisiana, Maryland, Mississippi, North Dakota, Washington, West Virginia or Washington, DC, this is the app you’ll use.

Delaware, New Mexico and Michigan are also using web portals for residents to access their vaccination status online.

New Yorkers have two app options, including the Excelsior Pass app and NYC Covid Safe.

We’ll continue to keep an eye out for other states that have apps and features to store your COVID-19 vaccine card online.

What if my state doesn’t have an app to store my card?

If your state doesn’t have an iPhone or Android app to store your card, there are other ways to store it on your phone. The US doesn’t have a single online system or app you can use to show proof of vaccination on your phone. Instead, what qualifies as proof varies by city, county and even business.

Some places may accept a picture of your vaccination card. It’s a confusing mess, to put it mildly. I strongly urge you to take a few minutes to research what your city, county or state will accept as proof, as it can vary.

For example, concert producer AEG Presents will accept a «physical copy of a COVID-19 Vaccination Record Card, a digital copy of such card or such other proof as is permitted locally.»

Along with school mandates, hundreds of colleges are also requiring students and employees to be vaccinated. Seattle University, for example, requires students to be vaccinated to attend in-person classes via an online form that uploads photos of the front and back of the vaccination card.

When in doubt, look for information on the business’s website, or call the local health department and ask for clarification. This is bound to save you time, headaches and being turned away at the door.

Can I use Google Pay or Apple Wallet to store my card?

Yes. If you have an iPhone ($330 at Amazon), you can store your COVID-19 vaccination card on your Apple Wallet to present whenever you need to show you’re fully vaccinated. (You can keep a copy in the Health app, too.) You can also keep your card handy on your Apple Watch with the latest WatchOS update.

Over on Android, you can add your vaccine card to the Google Pay app. I need to remind myself each time where my card is in Google Pay (you can find it by tapping the card area up at the top of the app), so I added a shortcut icon to my home screen to quickly find it.

Samsung Pay can also store your vaccine record

Samsung now gives Galaxy phone owners the option to add proof of vaccination to Samsung Pay,its wallet app. By having direct access to your vaccination record, youwon’t have to fiddle around with creating photo albums and tappingthrough multiple screens before you’re able to show it to a bouncer atyour local watering hole.

To add your card to Samsung Pay, you’ll need to download the CommonHealth app(Samsung’s partner) from the Google Play Store. Follow the prompts inthe app to verify your vaccination status. Once the app confirms you’veindeed gotten the shots, you’ll be prompted to download a Smart HealthCard to Samsung Pay.

That card is what you’ll then show to anyone requesting you show proof of vaccination.

Will a picture of my vaccine card work?

The simplest way to have a digital record of your vaccine status is to snap a picture of your vaccination card and keep it on your phone. The CDC even recommends keeping a picture of your card as a backup copy.

Simply use the camera app on your phone to snap the photo. You can favorite the photo to quickly locate it or store it in a notes app, a folder or somewhere that’s easy to remember so you don’t have to endlessly scroll your camera roll to find it. Make sure you’re in a well-lit area and get close enough to the card that its dates and details are legible. I also suggest putting the card on a dark surface, while remaining conscious of shadows of your arms or the phone on the card itself.

Here’s an example of one way to save your vaccination card as a new photo album. On an iPhone, open the Photos app, select the Albums tab and then tap the plus (+) sign in the top-left corner followed by New Album. Give the album a name and then tap Save. Next, select the photos of your card to add them to the album.

On an Android phone, it depends on which app you’re using, but the process should generally be the same. If you’re using the Google Photos app, open the app and then select the picture of your vaccination card. Tap the three-dot menu button in the top-right corner, followed by the Add to Album button. Select +New album and give it a name such as «Vaccination Card» and tap the checkmark button when you’re done.

What else can I use?

I’ve had a large number of readers reach out to me about this article, each one offering advice and guidance about storing a proof of vaccination card.

Some suggestions include well-known airport security service Clear. In fact, some concert and exhibition halls require that attendees use Clear to verify their vaccination status to attend a show. You can go to clearme.com/healthpass to download the app and get your card added.

VaxYes is another service that verifies your vaccination status and then adds your vaccination card to your Apple Wallet. I’ve read that you can add your card to the Google Pay app, but after signing up and going through the process myself, I don’t see the option on a Pixel 5 running Android 12.

If your local municipality or employer used the CDC’s Vaccine Administration Management System, then you can use the VAMS website to access your vaccination records. I had more than one reader reach out to me about using this system to show proof of vaccination, but without an account myself, I’m unable to go through the process of accessing a vaccination record.

Another suggestion I received from multiple readers is to use a scanner app on your phone and store a scanned copy of your vaccination card in something like your OneDrive personal vault or a password manager (almost all of them offer some sort of secure file storage) instead of storing the photo in Google Photos or Apple’s iCloud photos. On an iPhone, you can use the scanner that’s built into the Notes app. On Android, Google’s Stack PDF scanner will be enough to get the job done.

This story updates as the national vaccine conversation continues. For more information about the booster shots from Pfizer, Moderna and Johnson & Johnson, make sure to read this. We have up-to-date details about the omicron variant
.

The information contained in this article is for educational and informational purposes only and is not intended as health or medical advice. Always consult a physician or other qualified health provider regarding any questions you may have about a medical condition or health objectives.

Technologies

AI Slop Is Destroying the Internet. These Are the People Fighting to Save It

Technologies

The Sun’s Temper Tantrums: What You Should Know About Solar Storms

Solar storms are associated with the lovely aurora borealis, but they can have negative impacts, too.

Last month, Earth was treated to a massive aurora borealis that reached as far south as Texas. The event was attributed to a solar storm that lasted nearly a full day and will likely contend for the strongest of 2026. Such solar storms are usually fun for people on Earth, as we are protected from solar radiation by our planet’s atmosphere, so we can just enjoy the gorgeous greens and pretty purples in the night sky.

But solar storms are a lot more than just the aurora borealis we see, and sometimes they can cause real damage. There are several examples of this in recorded history, with the earliest being the Carrington Event, a solar storm that took place on Sept. 1, 1859. It remains the strongest solar storm ever recorded, where the world’s telegraph machines became overloaded with energy from it, causing them to shock their operators, send ghost messages and even catch on fire.

Things have changed a lot since the mid-1800s, and while today’s technology is a lot more resistant to solar radiation than it once was, a solar storm of that magnitude could still cause a lot of damage.

What is a solar storm?

A solar storm is a catchall term that describes any disturbance in the sun that involves the violent ejection of solar material into space. This can come in the form of coronal mass ejections, where clouds of plasma are ejected from the sun, or solar flares, which are concentrated bursts of electromagnetic radiation (aka light).

A sizable percentage of solar storms don’t hit Earth, and the sun is always belching material into space, so minor solar storms are quite common. The only ones humans tend to talk about are the bigger ones that do hit the Earth. When this happens, it causes geomagnetic storms, where solar material interacts with the Earth’s magnetic fields, and the excitations can cause issues in everything from the power grid to satellite functionality. It’s not unusual to hear «solar storm» and «geomagnetic storm» used interchangeably, since solar storms cause geomagnetic storms.

Solar storms ebb and flow on an 11-year cycle known as the solar cycle. NASA scientists announced that the sun was at the peak of its most recent 11-year cycle in 2024, and, as such, solar storms have been more frequent. The sun will metaphorically chill out over time, and fewer solar storms will happen until the cycle repeats.

This cycle has been stable for hundreds of millions of years and was first observed in the 18th century by astronomer Christian Horrebow.

How strong can a solar storm get?

The Carrington Event is a standout example of just how strong a solar storm can be, and such events are exceedingly rare. A rating system didn’t exist back then, but it would have certainly maxed out on every chart that science has today.

We currently gauge solar storm strength on four different scales.

The first rating that a solar storm gets is for the material belched out of the sun. Solar flares are graded using the Solar Flare Classification System, a logarithmic intensity scale that starts with B-class at the lowest end, and then increases to C, M and finally X-class at the strongest. According to NASA, the scale goes up indefinitely and tends to get finicky at higher levels. The strongest solar flare measured was in 2003, and it overloaded the sensors at X17 and was eventually estimated to be an X45-class flare.

CMEs don’t have a named measuring system, but are monitored by satellites and measured based on the impact they have on the Earth’s geomagnetic field.

Once the material hits Earth, NOAA uses three other scales to determine how strong the storm was and which systems it may impact. They include:

Geomagnetic storm (G1-G5): This scale measures how much of an impact the solar material is having on Earth’s geomagnetic field. Stronger storms can impact the power grid, electronics and voltage systems.
Solar radiation storm (S1-S5): This measures the amount of solar radiation present, with stronger storms increasing exposure to astronauts in space and to people in high-flying aircraft. It also describes the storm’s impact on satellite functionality and radio communications.
Radio blackouts (R1-R5): Less commonly used but still very important. A higher R-rating means a greater impact on GPS satellites and high-frequency radios, with the worst case being communication and navigation blackouts.

Solar storms also cause auroras by exciting the molecules in Earth’s atmosphere, which then light up as they «calm down,» per NASA. The strength and reach of the aurora generally correlate with the strength of the storm. G1 storms rarely cause an aurora to reach further south than Canada, while a G5 storm may be visible as far south as Texas and Florida. The next time you see a forecast calling for a big aurora, you can assume a big solar storm is on the way.

How dangerous is a solar storm?

The overwhelming majority of solar storms are harmless. Science has protections against the effects of solar storms that it did not have back when telegraphs were catching on fire, and most solar storms are small and don’t pose any threat to people on the surface since the Earth’s magnetic field protects us from the worst of it.

That isn’t to say that they pose no threats. Humans may be exposed to ionizing radiation (the bad kind of radiation) if flying at high altitudes, which includes astronauts in space. NOAA says that this can happen with an S2 or higher storm, although location is really important here. Flights that go over the polar caps during solar storms are far more susceptible than your standard trip from Chicago to Houston, and airliners have a whole host of rules to monitor space weather, reroute flights and monitor long-term radiation exposure for flight crews to minimize potential cancer risks.

Larger solar storms can knock quite a few systems out of whack. NASA says that powerful storms can impact satellites, cause radio blackouts, shut down communications, disrupt GPS and cause damaging power fluctuations in the power grid. That means everything from high-frequency radio to cellphone reception could be affected, depending on the severity.

A good example of this is the Halloween solar storms of 2003. A series of powerful solar flares hit Earth on Oct. 28-31, causing a solar storm so massive that loads of things went wrong. Most notably, airplane pilots had to change course and lower their altitudes due to the radiation wreaking havoc on their instruments, and roughly half of the world’s satellites were entirely lost for a few days.

A paper titled Flying Through Uncertainty was published about the Halloween storms and the troubles they caused. Researchers note that 59% of all satellites orbiting Earth at the time suffered some sort of malfunction, like random thrusters going offline and some shutting down entirely. Over half of the Earth’s satellites were lost for days, requiring around-the-clock work from NASA and other space agencies to get everything back online and located.

Earth hasn’t experienced a solar storm on the level of the Carrington Event since it occurred in 1859, so the maximum damage it could cause in modern times is unknown. The European Space Agency has run simulations, and spoiler alert, the results weren’t promising. A solar storm of that caliber has a high chance of causing damage to almost every satellite in orbit, which would cause a lot of problems here on Earth as well. There were also significant risks of electrical blackouts and damage. It would make one heck of an aurora, but you might have to wait to post it on social media until things came back online.

Do we have anything to worry about?

We’ve mentioned two massive solar storms with the Halloween storms and the Carrington Event. Such large storms tend to occur very infrequently. In fact, those two storms took place nearly 150 years apart. Those aren’t the strongest storms yet, though. The very worst that Earth has ever seen were what are known as Miyake events.

Miyake events are times throughout history when massive solar storms were thought to have occurred. These are measured by massive spikes in carbon-14 that were preserved in tree rings. Miyake events are few and far between, but science believes at least 15 such events have occurred over the past 15,000 years. That includes one in 12350 BCE, which may have been twice as large as any other known Miyake event.

They currently hold the title of the largest solar storms that we know of, and are thought to be caused by superflares and extreme solar events. If one of these happened today, especially one as large as the one in 12350 BCE, it would likely cause widespread, catastrophic damage and potentially threaten human life.

Those only appear to happen about once every several hundred to a couple thousand years, so it’s exceedingly unlikely that one is coming anytime soon. But solar storms on the level of the Halloween storms and the Carrington Event have happened in modern history, and humans have managed to survive them, so for the time being, there isn’t too much to worry about.

Technologies

TMR vs. Hall Effect Controllers: Battle of the Magnetic Sensing Tech

The magic of magnets tucked into your joysticks can put an end to drift. But which technology is superior?

Competitive gamers look for every advantage they can get, and that drive has spawned some of the zaniest gaming peripherals under the sun. There are plenty of hardware components that actually offer meaningful edges when implemented properly. Hall effect and TMR (tunnel magnetoresistance or tunneling magnetoresistance) sensors are two such technologies. Hall effect sensors have found their way into a wide variety of devices, including keyboards and gaming controllers, including some of our favorites like the GameSir Super Nova.

More recently, TMR sensors have started to appear in these devices as well. Is it a better technology for gaming? With multiple options vying for your lunch money, it’s worth understanding the differences to decide which is more worthy of living inside your next game controller or keyboard.

How Hall effect joysticks work

We’ve previously broken down the difference between Hall effect tech and traditional potentiometers in controller joysticks, but here’s a quick rundown on how Hall effect sensors work. A Hall effect joystick moves a magnet over a sensor circuit, and the magnetic field affects the circuit’s voltage. The sensor in the circuit measures these voltage shifts and maps them to controller inputs. Element14 has a lovely visual explanation of this effect here.

The advantage this tech has over potentiometer-based joysticks used in controllers for decades is that the magnet and sensor don’t need to make physical contact. There’s no rubbing action to slowly wear away and degrade the sensor. So, in theory, Hall effect joysticks should remain accurate for the long haul.

How TMR joysticks work

While TMR works differently, it’s a similar concept to Hall effect devices. When you move a TMR joystick, it moves a magnet in the vicinity of the sensor. So far, it’s the same, right? Except with TMR, this shifting magnetic field changes the resistance in the sensor instead of the voltage.

There’s a useful demonstration of a sensor in action here. Just like Hall effect joysticks, TMR joysticks don’t rely on physical contact to register inputs and therefore won’t suffer the wear and drift that affects potentiometer-based joysticks.

Which is better, Hall effect or TMR?

There’s no hard and fast answer to which technology is better. After all, the actual implementation of the technology and the hardware it’s built into can be just as important, if not more so. Both technologies can provide accurate sensing, and neither requires physical contact with the sensing chip, so both can be used for precise controls that won’t encounter stick drift. That said, there are some potential advantages to TMR.

According to Coto Technology, who, in fairness, make TMR sensors, they can be more sensitive, allowing for either greater precision or the use of smaller magnets. Since the Hall effect is subtler, it relies on amplification and ultimately requires extra power. While power requirements vary from sensor to sensor, GameSir claims its TMR joysticks use about one-tenth the power of mainstream Hall effect joysticks. Cherry is another brand highlighting the lower power consumption of TMR sensors, albeit in the brand’s keyboard switches.

The greater precision is an opportunity for TMR joysticks to come out ahead, but that will depend more on the controller itself than the technology. Strange response curves, a big dead zone (which shouldn’t be needed), or low polling rates could prevent a perfectly good TMR sensor from beating a comparable Hall effect sensor in a better optimized controller.

The power savings will likely be the advantage most of us really feel. While it won’t matter for wired controllers, power savings can go a long way for wireless ones. Take the Razer Wolverine V3 Pro, for instance, a Hall effect controller offering 20 hours of battery life from a 4.5-watt-hour battery with support for a 1,000Hz polling rate on a wireless connection. Razer also offers the Wolverine V3 Pro 8K PC, a near-identical controller with the same battery offering TMR sensors. They claim the TMR version can go for 36 hours on a charge, though that’s presumably before cranking it up to an 8,000Hz polling rate — something Razer possibly left off the Hall effect model because of power usage.

The disadvantage of the TMR sensor would be its cost, but it appears that it’s negligible when factored into the entire price of a controller. Both versions of the aforementioned Razer controller are $199. Both 8BitDo and GameSir have managed to stick them into reasonably priced controllers like the 8BitDo Ultimate 2, GameSir G7 Pro and GameSir Cyclone 2.

So which wins?

It seems TMR joysticks have all the advantages of Hall effect joysticks and then some, bringing better power efficiency that can help in wireless applications. The one big downside might be price, but from what we’ve seen right now, that doesn’t seem to be much of an issue. You can even find both technologies in controllers that cost less than some potentiometer models, like the Xbox Elite Series 2 controller.

Caveats to consider

For all the hype, neither Hall effect nor TMR joysticks are perfect. One of their key selling points is that they won’t experience stick drift, but there are still elements of the joystick that can wear down. The ring around the joystick can lose its smoothness. The stick material can wear down (ever tried to use a controller with the rubber worn off its joystick? It’s not pleasant). The linkages that hold the joystick upright and the springs that keep it stiff can loosen, degrade and fill with dust. All of these can impact the continued use of the joystick, even if the Hall effect or TMR sensor itself is in perfect operating order.

So you might not get stick drift from a bad sensor, but you could get stick drift from a stick that simply doesn’t return to its original resting position. That’s when having a controller that’s serviceable or has swappable parts, like the PDP Victrix Pro BFG, could matter just as much as having one with Hall effect or TMR joysticks.