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Yamara
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18:09, 14 March 2008 (UTC)
News radio: The easiest method to access standard time is to listen to the news on radio. National radio news programs set their clocks to the transmissions from the standards departments of their respective countries. - This is an Opinion 70.251.161.12 17:01, 5 May 2006 (UTC)
Aren't these usually called clock radios? Evertype 18:17, 17 April 2006 (UTC) - No
I'm missing a clear statement whether or not a simple radio clock purchased in one country will work in the other.
From reading the text I'd say rather not, but it doesn't say so.
Else it is written quite understandable - thinks Steffen.
The "Performance" section seems to bring up a few relevant issues (for example, the need to orient a clock in a window properly, and the necessity of setting the time zone) and many irrelevant ones (like the supposed unavailability of tech support for these clocks), but uses a very sarcastic tone:
A typical radio clock will be accurate to the millisecond but may be off by an hour or two, because the user failed to understand the manual. These range from a single sheet of paper, folded twice, to a booklet the size of a business card and 100 pages (50 leaves) long, in both English and Spanish. In most cases, the timepiece was designed by highly-skilled engiteers using specifications published by the NIST, then manufactured in the Far East, usually China. Design parameters are highly subject to cost constraints, which limit the number of chips and the number of switches, or buttons: in general, it is cheaper to have five buttons and 5! (30) modes than to have 30 buttons and one mode. The resulting state-machine diagrams are so complex that the engineers can barely understand them. The engineers then pass on their specifications to technical writers, who may or may not be fluent in English, and are not allowed to replicate the engineers' diagrams, lest the user understand the complexity of the clock's design. A user who doesn't understand may try to cotact the manufacturer, but they will never reach a person who can answer the question: the engineer speaks only Mandarin and never answers the phone, and there is "no" Technical Support department.
This ought to be rolled back, or heavily edited. I will roll it back if no one steps up to edit it. ThinkingInBinary 01:14, 22 August 2007 (UTC)
The article currently correctly points out that "No GPS receiver directly computes time or frequency, rather they use GPS to discipline an oscillator".
However, my understanding is that *every* radio clock (and NTP) does the same thing, so it is misleading to imply that *only* GPS receivers do this.
All radio clocks including GPS (and also NTP) use a local oscillator to maintain an approximate time, then use the received signal to either (a) adjust the oscillator clock frequency (directly, or indirectly by adjusting the clock divider), or (b) force the counter to the correct time, then continue to use the oscillator to increment the time, or (c) both.
Or is there some subtlety that I am missing, or some other kind of clock that somehow works differently? -- 68.0.124.33 ( talk) 00:11, 2 March 2008 (UTC)
Editor ParaGreen13 maintains that inexpensive radio clocks are "reasonably accurate" between syncs, claiming that ordinary quartz clocks, watches, etc., are good to a half a second a day "at worst."
This page on crystal accuracy disagrees: [1] He cites 20 ppm, which is 5x better than a typical crystal.. and allows for almost 2 seconds a day worth of wrong.
A half second a day would be about 6 ppm, and that would be a very special crystal indeed. If there is a source (other than watch makers' sales literature) for this "half a second per day" figure, I would ask ParaGreen13 to please provide it.
ParaGreen13 also claims "Oftentimes it's closer to 1.8 sec. or less/week" and "Usually not +/- by more than 1-2 sec/week". 1.8 sec/week is just about at three ppm and 1 sec/week, better than two ppm. These figures are flatly unachievable without a crystal oven (and then you get much much better, in the range of one part per billion).
It is true that it is possible to find individual watches (usually not the cheapest) that perform that well or even better, but that does not say anything about the quality of components in a $20 radio clock.
The watch benefits not only from a crystal but also from the constant temperature that's achieved by you wearing it on your wrist. And many higher-end watches "discipline" their oscillator, making fine adjustments if you reset them by small increments - after doing a few corrections "to the second" you will likely not have to do it again, or at least not as much.
The inexpensive circuits in $20 radio clocks do not have top-quality watch crystals, nor any constant-temperature mechanism, nor a disciplining mechanism.
Even at half a second a day, after a few days of no signal (not uncommon depending on where you live WRT the time standard transmitter) you can be off by several seconds. To the person who bought the radio clock for "atomic clock" accuracy I doubt this would be considered "quite reasonably accurate." Jeh ( talk) 07:34, 29 December 2009 (UTC)
Under external link "NPL list of Standard Time and Frequency Transmissions" pointing to http://www.npl.co.uk/time/measurement_time/time_trans.html is broken. — Preceding unsigned comment added by ThePianoGuy ( talk • contribs) 11:38, 13 February 2011 (UTC)
The US loran system has been shut down.
http://www.navcen.uscg.gov/?pageName=loranMain — Preceding unsigned comment added by 76.90.10.240 ( talk) 03:13, 13 October 2011 (UTC)
There cannot be two different signals both broadcast on the same frequency from the same location, so one of the lines in this table must be wrong. 212.159.69.4 ( talk) 17:02, 31 December 2011 (UTC)
I noticed this sentence in the article (section 1.1.2 as of this writing, 2016-01-31 1208.19 UTC) and I was struck by the fact that it is not only true of "Modern radio clocks" that are "referenced to atomic clocks" and which "provide access to high-quality atomic-derived time over a wide area using inexpensive equipment" but that it is also true of all timepieces which exist anywhere on earth as of right now or indeed at any point in the past, and, I say with unusual certainty, any timepiece which may be manufactured at any point in the future.
I am relatively inexperienced with Wikipedian issues beyond grammar, spelling, and blatant factual inaccuracies, but do basic tautologies like "x is suitable for any purpose which does not require higher accuracy than x can provide" really have a place here? If your scientific "or other" work only requires a timepiece that's accurate twice a day, an old saying suggests that even a broken clock would be suitable. Mattman00000 ( talk) 12:18, 31 January 2016 (UTC
It has been my experience based on a half-dozen or more WWVB radio controlled clocks, that many of them will sometimes misset themselves (say by 10 minutes or more), probably when the signal is weak and/or there is interference. I use triac lamp dimmers which are notorious for causing AM radio noise. I always advise never using them directly as alarm clocks, but instead using them to check non-radio-controlled alarm clocks. A digital shortwave radio that can get a standard time signal, such as WWV 10.000 MHz, can help find goofy missettings. Note that when comparing an audio signal with a visual signal, that there are possibly two different personal equations involved. agb — Preceding unsigned comment added by 173.233.167.63 ( talk) 22:55, 8 May 2017 (UTC)
Same here. Mine went screwy around midnight and woke me up!!
Hi, apparently there is a classified uplink/downlink frequency which uses FHSS but with a long duration low noise setup the signals can be decoded into the encrypted payload and time signal. Perhaps this should be added as it can be used as a reference similar to GPS/GNSS/Galileo ? same with
I've noticed Radio 4 is on the list for the UK, but I can't seem to find very much proof this is used by radio clocks as a time signal. Most radio clocks in the UK seem to be set to MSF (I couldn't find an example of any using 198Khz), and MSF covers the whole country. The reference in the URL is a deadlink, and web archive just shows it as a list of stations. The closest evidence I could find was https://www.nxp.com/docs/en/application-note/AN1597.pdf Should it be removed? I couldn't find much evidence on NPL's website apart from this http://web.archive.org/web/20180422095850/https://www.npl.co.uk/science-technology/time-frequency/products-and-services/time/droitwich-bulletins
I didn't time to dig into it, but here is the original BBC technical doc referenced by the NXP application note; hope this can help:
L.F. RADIO-DATA: Specification of BBC phase-modulated transmissions on long-wave - [2] Strangerpete ( talk) 00:33, 27 June 2020 (UTC)
The above is correct, Radio 4 is used for the setting of electricity meters, not for consumer radio clocks. Should it still be on this list? Jayflux ( talk) 19:05, 2 May 2021 (UTC)
WWV on 25 MHz is broadcasting with a power of 2.5 kW [1]
References
Having the station list on this page is a bit misleading in some cases, as radio clocks aren't run off of all of them. For example, WWVB, rather than WWV, is the source for USA radio clocks. A list of time stations would be very useful on its own, though, as they're used for research and the BIPM list sometimes misses details. Thoughts on moving the table to a "time standard station" page? Vannevarmorgan ( talk) 01:36, 30 March 2021 (UTC)