> grids were owned by many small regional power companies; thus, voltages and frequencies (42Hz was quite common) could vary a lot between each other
It always amazes me that some countries are still operating on multiple mains voltages and/or frequencies while sharing a common plug standard, such as Brazil or notably Japan (where the 50/60 Hz division apparently runs through a densely populated area)!
Fortunately most devices I bring with me when traveling don't care and adapt to whatever, but being able to plug a 110 V hairdryer into a 230 V outlet without any form of adapter sounds scary.
A difference in frequency is much less of an issue than a difference in voltage, I would have thought. Especially as 50 and 60Hz are fairly close to each other.
The only big problems I can think of are devices that use the frequency as a reference, such as motors and clocks. But even then, they wouldn’t break, they’d just run at the wrong speed.
A difference in frequency is not that big of a problem... except for the fact that you can't easily transfer power across the two grids.
Japan has some power conversion stations, but when the Tohoku earthquake and tsunami of 2011 knocked off several powerplants in the 50 Hz half of the country (including Fukushima), they could not transfer enough power from the other side, and the suffered many blackouts, even though the 60 Hz half of the country had power to spare.
I've been wondering that too recently, and apparently it wasn't that big of a deal [1] – more recent analog TVs weren't that susceptible to mains interference of the sort that benefited from being synchronized to the frame rate.
In other words, the mains frequency was never used as a frequency source for TVs, and the apparent frequency match was only to make interference patterns not wander around the screen.
> The only big problems I can think of are devices that use the frequency as a reference, such as motors and clocks.
This was my March mindfuck:
That there are periods every couple weeks when the WHOLE ELECTRICITY GRID of a country is run with higher/lower frequency for a period of time to get your Chinese oven clocks back into sync.
Long-term grid frequency stability is something you take for granted, until it suddenly fails, like in most of Europe back in 2018, due to a political disagreement between Serbia and Kosovo: https://www.reuters.com/article/idUSL5N1QP2FF/
I also find it quite funny that our cheap oven clock is probably among the most precise (non-internet connected) ones in our apartment :)
How effective is receiving precision time from a GNSS constellation within structures, urban areas, and other challenging SNR envs? Another comment mentions cell towers broadcast this unencrypted and without the need for service, so perhaps the solution is to instead require strong SLAs around that service, with the gov potentially paying for that service level?
I feel like once you're concerned about SLAs for precision timekeeping, you need to start worrying about spoofing as well, which is tricky to combat in an inherently unidirectional protocol.
Galileo has an interesting signal authentication service [1], but even that is subject to replay attacks by definition (although you can't skip ahead a receiver's time).
In comparison, networked bidirectional protocols like NTP are almost trivially secure-able, by including a challenge in the request and a cryptographic signature over the response.
Yep, reception is a real problem with straight GNSS. WWVB suffered from it too, and cellular (which is locked to GPS) is a big upgrade. I suppose that now the thing to do is wait for the $0.10 cellular clock chip that makes it easy.
My interest is as a bit of a precision time enthusiast and an advocate of public goods. We’re awash in “good time”, GNSS, RF, NTP over IP, cellular, but it still feels like there is a gap to fill to make precision time super cheap and ubiquitous. Getting time over mains power or other previously convenient but potentially low precision sources should be over, but getting precision time should be as easy and reliable as mains power. Thanks for riffing with me!
Noted my car got time from GPS the other day and it got me thinking, why aren't there unencrypted packets on all wifi that distribute NTP time so my oven/microwave/alarm/etc can grab it from any wifi it can see (even if it's not paired to them) - bonus points if APs also hand out local TZ data
Phone networks can already do this. And its true broadcast, you can decode it passively without ever connecting to the network, so no SIM/transmission required.
I have no idea this is actually enabled in networks in practice, but the specification exists.
And in my experience, it's often wrong on some towers. I can't enable the setting on my phone to automatically set the time from the network, because if I do, it gets several minutes out of sync with the real time, which breaks TOTP generation.
Yeah, a large German cell provider had their time off by a couple of minutes some years back, which made the news as it resulted in people's alarms ringing late and them being late to work/school etc.
Hopefully modern phones prioritize GPS or NTP derived time and timezone information over NITZ (which is how networks provide it). At least Android has the capability to do so, but it's ultimately up to device manufacturers, as far as I understand [1].
Could the detection and reporting of this inaccuracy be crowdsourced, either with mobile devices or perhaps SDRs? Fetch tower time, fetch real time over GNSS or NTP, report delta with tower ID and drift to a central server? Perhaps even include a map, like the map of GPS error rates derived from ADS-B data feeds.
I'm almost certain that at least Apple already has such a database on the operator level, i.e. a list of MNCs and the (non-)trustworthiness of NITZ. I vaguely remember seeing some carrier settings keys to that extent somewhere.
Distributed monitoring and centralized reporting would be used to correct anomalous towers providing bad time and can provide independent verification of precision. It is not enough to provide a service; you must also have a system to validate it, and correct when needed.
Unencrypted broadcast NTP timestamps sound like a good idea until your neighbor starts broadcasting false timestamps to prevent your loud smart leaf blower from charging overnight :)
It's probably about time for an update that can work with more compact receivers.
Governments(Or an industry group, or really anyone) could publish digitally signed timestamps every second with a a key that doesn't change, and you could have a BLE profile for sharing them.
There used to be a local hydro generation that fed the local city, they had 2 clocks on the wall, one on the local grid and one on the national one - some time late at night they'd speed up/slow down the local grid to keep the clocks in sync
It's surprisingly hard to keep a clock accurate over time. Typical crystal oscillators can gain or lose seconds per day. If you want to do better than that, you either need internet access (for NTP), a radio receiver of some kind (for atomic clock broadcasts, GPS, etc.), or a significantly more expensive oscillator. Having a frequency reference with perfect long-term accuracy that any electrically-powered clock can use for free is pretty convenient!
I've often wondered how hard it would be to make portable battery-powered clocks use 60 Hz noise as a timekeeping source. Maybe I should make a project out of it.
> Typical crystal oscillators can gain or lose seconds per day.
Are you sure?
I only owned a quartz watch when I was a kid, but all sources I find on the web say even the lowest quality quartz watch movements are accurate to +- 20-30 seconds a month.
For comparison: my several decades old manual Poljot loses some seconds per day.
The Casio G-Shock I got in the 90s was ~66 ppm fast, which worked out to ~5 seconds/day. There are cheap crystals on Digi-Key with ~10 ppm accuracy, which is around 0.86 seconds/day. But crystals drift with age (and a tiny bit with temperature). Perhaps watches have improved since I last looked, but I would want to measure the actual real-world accuracy before believing anything better than 1 second/day.
The problem is that grid frequency has terrible mid-term performance. The frequency itself will be reasonably close to 50/60Hz, but it's guaranteed to be off by a little bit due to the way it operates - and that small offset accumulates over time.
For example, the European supergrid only makes time corrections if it has drifted by more than 20 seconds. That's good enough for the clock on your microwave, but it's pretty bad compared to literally any other time source.
A few cents, as far as I understand, but that's not the only problem:
You can get significantly more precision using an oven-controlled oscillator (frequency is temperature-dependent, and it's easier and more precise to control temperature to a known high setpoint than to compensate for the temperature-frequency curve using a thermometer), but these are, as the name implies, small ovens that consume additional electricity (on the order of 1-2 W, as far as I know).
An additional base load of 1-2 W per oven and microwave would be pretty bad for the energy budget on a global scale, so just providing a time source from the power line they're already connected to is more efficient :)
Other than oven-based oscillators, you can also use temperature-corrected oscillators; the Apple Watch does that, for example, and is supposedly about four times more accurate than a non-temperature-corrected MEMS, which in turn is already better than a quartz oscillator [1].
Not that it matters much, given that all models have at least a GPS receiver these days, as well as a battery life of about a day without charging, but I suppose it's a real benefit to all Apple Watch users working in faraday cage isolated bunkers without Wi-Fi :)
> A few cents, as far as I understand, but that's not the only problem
Nitpick: looking on Digi-Key, in quantity, a sub-ppm oscillator is ~5x more expensive than a 10 ppm crystal -- ~85 cents for the cheapest TCXO I can find vs. ~18 cents for a crystal. The frequencies are also much higher (tens of megahertz), which won't help with the power consumption.
It depends. On the lower end of the spectrum, there are high volume products that offer somewhat better performance for just a tiny increase in cost, as mentioned in other comments. On the higher end of the spectrum there are laboratory-grade oscillators, for example the legendary Hewlett-Packard 10811 [1] and similar, which cost hundreds to thousands of dollars. These overlap in price with the lower end atomic clocks.
Here in Brazil we have voltages in different regions but we also have different voltages inside the home. My washer has its separate 220v circuit while the rest of the home is 110v.
As far as I know that’s usually a split-phase system: You get 110V between either phase and neutral, and 220V between the phases.
In a three-phase system (like the ones used in most of Europe), that effect isn’t as pronounced since you usually have at most 120 degrees phase difference instead of 180 and the voltage between two phases is less than double, so less appliances make use of that (I think some stoves do).
> As far as I know that’s usually a split-phase system: You get 110V between either phase and neutral, and 220V between the phases.
We Brazilians tend to call it "110V", but it's often a three-phase system with 127V between phase and neutral and 220V between phases.
Or sometimes it's 115V from phase to neutral and 230V from phase to phase (probably a split-phase system like you said). And in that case, us Brazilians would still call the lower voltage "110V", and the higher voltage "220V".
You can't trust a Brazilian when they say the voltage is "110V" or "220V". These numbers are only an approximation, which might have been correct for some places a century or two ago.
A Brazilian would say "110V" for all these lower voltages between 115V and 127V, and would say "220V" for all these voltages between 208V and 230V.
At least the frequency is always 60Hz (unlike the rest of South America, which uses 50Hz; we have to use HVDC links when importing or exporting electricity to the neighboring countries).
Using HVDC to interconnect async grids is very common.
This presentation is a nice deep dive on the situation in Europe: we are even building HVDC “corridors” embedded inside some of the sync grids. Pricey gear but valuable too!
HVDC corridors make sense because it's functionally impossible to build new overhead transmission lines anywhere, so operators are forced to bury the transmission lines. But buried AC transmission lines have terrible loss and are super expensive, buried HVDC lines are slightly less expensive (but require expensive terminal stations), and have much lower losses.
> it's functionally impossible to build new overhead transmission lines anywhere
This isn't really true, new overhead lines are being built all over the place. It definitely depends where they're being built and there is definitely strong opposition from councils in e.g. some parts of Germany, but see for example in the Netherlands there are definitely new overhead lines being built: https://www.tennet.eu/nl/projecten/provincies/groningen/eems...
That being said it's true that it's much more challenging than it used to be to get planning permission.
> we are even building HVDC “corridors” embedded inside some of the sync grids
We also have that here in Brazil; the Xingu-Estreito and Xingu-Terminal Rio HVDC links run in parallel with the high-voltage AC links. On the other hand, the Madeira HVDC link (https://en.wikipedia.org/wiki/Rio_Madeira_HVDC_system) is AFAIK normally disconnected from the AC grid on the generation end (it has a direct connection, probably used to start up the power plants, but normally uses a back-to-back HVDC converter instead of it).
My local power company (in the USA) is known for running slightly higher voltage than the spec. In the past I have seen 127V - and wrote a letter complaining about it. Which probably got me on their list of annoying customers...
Currently it's at 121.8V - either they have finally adjusted the tap on the neighborhood transformer or there's a heavy load at the moment (hot water heaters running from people showering this morning?)
According to ANSI C84.1 (which I believe is the relevant US specification), there is a tolerance of +/- 5%, which would put 127V just barely out of spec.
I could imagine that utilities calculate some average base load and adjust transformers accordingly to accommodate the expected voltage drop, given that 110/120V is relatively low and drops can be significant?
Obviously not an expert, but I wonder if they run a higher voltage in order to give them some margin from frequency dropping too far below 60 Hz (caused by generators slowing down) during high load periods?
Just for comparison other countries that claim "230v" have that last one - 220-240v between the phase you get and neutral and 440v between phases if you get 3-phase
Europe also just doesn't need split-phase systems. A regular outlet will provide 230V @ 16A, or about 3.7kW. That's enough for virtually all household appliances, and single-phase 32A circuits for 7kW stoves are quite common too.
Households these days often do have a 3-phase hookup, but it's quite rare to have 3-phase equipment. Maybe a stove, and with the energy transition larger solar setups, electric car chargers, and large heat pumps. But most of the time that 3-phase hookup is just treated as three separate 1-phase sections.
DC “service” is run as a special tariff (for legacy elevators) and is actually provided by an on-site DC rectifier of some sort attached by PG&E to AC service.
I’m not really sure why it is tariffed and why the building doesn’t simply buy the equipment.
There were some buildings in downtown Chicago that had DC service even to the wall sockets. My grandfather had an office in such a building in the 1950s and had to make sure that any equipment (desk fans, radios, etc.) could run on DC.
Congratulations, you also read the IEEE article. At one point, it wasn't.
The problems are cost and value. Building owners probably can't afford to switch over or don't want to spend the money without getting something of value out of it.
As an American I find it difficult to buy power adaptors for travel to Italy. You can buy them in the US but once you're in Italy you discover they don't fit about half the outlets. The best solution is to visit a hardware store in Italy and buy some adapters and power strips. These usually work.
Type C plugs are compatible with both Type F and Type L sockets, it's just a more compact plug for when you have no need for ground. There are no Type C sockets.
So it's a mix of type F and Type L. Modern homes typically use combo sockets that accept both, or two sockets (one of each type) side by side in at least some of the fixtures. Italy uses a very cool modular system for electrical fixtures[1] which makes it easy to combine multiple plugs, or plugs and switches as well.
For those appliances that need to move a lot around the home (e.g., vacuum cleaners) to places where there could be no type F socket installed, you keep an F->L adaptor on the plug and basically never use it elsewhere.
It's almost impossible these days to have type E plugs with only the hole for ground and no springy pins on the side. So type E plugs are totally interoperable with both type E and type F sockets.
Those Type L plugs are pretty convenient for things like power strips where you want to plug in several things on the same strip. Schuko plugs are big and clunky and take up a lot of space, making for longer, bulkier power strips.
A problem arises when Schuko and Type L are used promiscuously in multi-standard sockets, since the former has slightly thicker prongs and it tends to loosen the contacts inside.
But then I suppose Europlug suffers from the same problem when used in CEE 7 type sockets.
This is a very interesting topic to me for some reason. I'd enjoy a website full of such explanations for a huge list of countries (I see that this website has some similar things.).
Also, I have found myself passively curious before about how far back you could go and find an outlet that you could plug a modern device into and have it work as expected.
The article is very comprehensive, and it even reports the rare biphase that some districts in Rome have, the only reason I know it is because many solar inverters works with this biphase, it can cause problems with car chargers (as the article reports) but also to some gas boilers that are very common in Italy.
Slightly (un)related also railways in Northern Italy used biphase supply until the 1970s. There is a nice Youtube video, let's see whether I remember to dig out the link a bit later and edit this comment.
I live in that part of Rome where we have 2 phases and no neutral.
I discovered being electrocuted and I could not understand why.
Fortunately heat pumps, "stupid" car chargers and other appliances work with no problems. But an installer told me that I could have had problems with smart car chargers and he refused to do the work.
It always amazes me that some countries are still operating on multiple mains voltages and/or frequencies while sharing a common plug standard, such as Brazil or notably Japan (where the 50/60 Hz division apparently runs through a densely populated area)!
Fortunately most devices I bring with me when traveling don't care and adapt to whatever, but being able to plug a 110 V hairdryer into a 230 V outlet without any form of adapter sounds scary.