I used to have a bip and loved it. The big thing was battery life and always on screen. It used a reflective LCD screen to do it. No newer amazefits use them.
I’ve since moved to using COROS watches. Not as cheap but really good. Always screen, weeks of battery. Even GPS functions are efficient . Recently did 11 hr hike with GPS and only used about 23% battery.
I really want a smartwatch with proper always on screen (so memory LCD, like those COROS ones), but I also need LTE so I don't have to bring my phone on short errands. Unfortunately no such product currently exists for some reason.
The Apples, Galaxies and Pixels offer always-on, but they dim down a lot in order to not drain the power, which kind of defeats the purpose. A memory LCD screen on one of these watches would be perfect for me.
Yes, this multiplies the complexity. When you talk to ATC you always need your tail number and airplane model. Why? Because a landing Cessna 150 is moving at 70mph. An incoming jet is moving at 130mph. And the jet can’t just slow down to 70 or it will fall out of the sky. They need to consider aircraft performance in all aspects of planning.
We just got Apple Watches for our 11 and 13 year olds. It is a decent middle ground, as up to now we’ve been very limiting of their screen time.
Our district has strict blocks in place at school, but most kids still already have phones. We did it for that reason and so so we don’t introduce phones at the same time they start driving (which is when we figured they’d actually need it)
One thing I wasn’t quite prepared for is kids use huge group chats that result in hundreds of messages a day. Learned how to mute discussions really quick. You can also limit access to groups with parental controls.
Key is talking to your kids regularly and helping them navigate life. Real and digital.
Reaching everywhere is arguably a bug with WiFi: The more transmitters you can hear and vice versa (besides the ones you're communicating with), the more congestion.
not necessarily always. for some use cases, it is better to have slow coverage than no coverage. Not for phones but temperature sensors or water leakage detectors are just two examples of what we could use this for today. However, bigger innovation will happen once we make unlicensed spectrum available.
Personally, I don't like there being more licensed spectrum.
I think more spectrum should be unlicensed
and therefore free for all who play by the rules.
> Not for phones but temperature sensors or water leakage detectors are just two examples of what we could use this for today.
You got Zigbee and LoRaWAN for that already. IKEA has water leakage detectors (which I highly recommend, they saved my ass already), and temp/hum sensors, go for Sonoff's lineup.
There's definitely use cases for long-range unlicensed communications, and I'm personally very excited about the technology. (Why on earth can two mobile phones still not exchange text messages directly over a couple hundred meters, for example?)
But in the case of Wi-Fi specifically, part of the success story of 5 GHz (besides having much more spectrum available than 2.4 GHz and having less noisy legacy applications cluttering it) is the lower maximum EIRP in most parts of it.
This forces everybody to have smaller (and if required more) cells – which is a big win in densely populated areas such as apartment buildings, for example.
> Why on earth can two mobile phones still not exchange text messages directly over a couple hundred meters, for example?
Because the cell network is designed around the towers managing resource allocation, instead of phones trying and hoping nobody else was trying at the same time. Doing it this way increases the total capacity of the network by a lot.
So to create a phone mesh network, you would effectively need to create an entire new protocol stack, probably some enhancements to the frontend/PHY for the initial connection establishment (two phones realizing they're in range of each other) and congestion handling. And depending on how you implemented it, it would be a power hog too, since listening for a tower broadcast requires much less juice than announcing your presence to the world and hoping someone is in range.
(I do actually think there is phone-to-phone communications buried somewhere in the standards, but it still requires the tower for coordination)
Phone-to-phone is probably better handled over WiFi and its variants. Simpler, easier to integrate, much less regulatory oversight.
Apple’s AWDL is hacky and ugly in lots of ways, but has been in market for a decade or more and enables phone to phone. If WiFi forum ever gets WiFi direct 2 off the ground it could be amazing.
But phone to phone is chicken and egg; users aren’t demanding it because there aren’t any killer apps, and there aren’t any killer apps because problems like identity, privacy, resiliency haven’t been solved, and those problems haven’t been solved because users aren’t demanding these apps.
Fully agreed. This seems like the exact type of thing that Apple should be able to break out of, like they did with AirDrop (yeah, there was Bluetooth OBEX before, but it was too slow/clunky to be very useful on most phones) and AirPlay (same story vs. Miracast over WiFi Direct).
Yet the only recent movement in that area was them cutting down on AirPlay to unknown contacts, reportedly due to governmental pressure.
So unfortunately I believe that there is just no interest of Apple to make any move there, despite being in an excellent position: iMessage would solve most problems of spam, discoverability etc. (they could make it so that you can only message preexisting contacts when offline).
But that's the thing: The primary use cases for something like this are the opposite of crowded urban areas, where infrastructure-based networking makes a lot more sense.
I'm not trying to save on data fees; I'd just love to do low-bandwidth peer to peer messaging with people nearby without any network around.
What if, for example, low-frequency 5G bands were available to such P2P applications as a secondary user, similarly to 5G WiFi and weather radars? If there's a network there, use that; if there isn't, do P2P!
The ability to push it through the air isn't there. You end up dumping a lot of power into the transmitter which then just heats the air around it rather than go anywhere because the oxygen is absorbing it.
It is however great for a non-contact point to point where you connect the xmitter and receiver by attaching adjoining faces together. Imagine a PCIe card where the edge connector had no electrical contacts it just sits in the slot and the connection is a 60GHz link between the card and the base board. With inductive power transfer you don't need any conductive contacts at all.
Its very cool and sciencey but the tranceivers are stupid expensive and the use case is really pretty limited.
Yep, the old WaveLAN stuff. I had a parallel port adapter version of that back in 1997 for an old Compaq Pentium laptop that I used for portable web browsing and telnet sessions.
I can’t tell if you’re being sarcastic or not, but half of the US thinks WE should have an authoritarian government. We may soon be in a post-democracy world.
Which is bonkers considering there is only one side that has attempted to overturn an election and has a candidate who openly admires autocrats and genocidal dictators.
I agree that we should extinguish authoritarianism where ever we find it, at home and abroad.
It is also important to recognize the link between this domestic authoritarianism and foreign. There is an incontrovertible link between the rise of American authoritarianism and Russia's attempt to invade Ukraine.
The control system knows what the rudder should be at all times for coordinated flight in the air, and keeping the nose and ground track aligned when near the ground for landing, performing the slip necessary when landing in a cross wind.
I’ve since moved to using COROS watches. Not as cheap but really good. Always screen, weeks of battery. Even GPS functions are efficient . Recently did 11 hr hike with GPS and only used about 23% battery.