Radio clock

(Redirected from GPS timing)

A radio clock or radio-controlled clock (RCC), and often colloquially (and incorrectly[1]) referred to as an "atomic clock", is a type of quartz clock or watch that is automatically synchronized to a time code transmitted by a radio transmitter connected to a time standard such as an atomic clock. Such a clock may be synchronized to the time sent by a single transmitter, such as many national or regional time transmitters, or may use the multiple transmitters used by satellite navigation systems such as Global Positioning System. Such systems may be used to automatically set clocks or for any purpose where accurate time is needed. Radio clocks may include any feature available for a clock, such as alarm function, display of ambient temperature and humidity, broadcast radio reception, etc.

A modern LF radio-controlled clock

One common style of radio-controlled clock uses time signals transmitted by dedicated terrestrial longwave radio transmitters, which emit a time code that can be demodulated and displayed by the radio controlled clock. The radio controlled clock will contain an accurate time base oscillator to maintain timekeeping if the radio signal is momentarily unavailable. Other radio controlled clocks use the time signals transmitted by dedicated transmitters in the shortwave bands. Systems using dedicated time signal stations can achieve accuracy of a few tens of milliseconds.

GPS satellite receivers also internally generate accurate time information from the satellite signals. Dedicated GPS timing receivers are accurate to better than 1 microsecond; however, general-purpose or consumer grade GPS may have an offset of up to one second between the internally calculated time, which is much more accurate than 1 second, and the time displayed on the screen.

Other broadcast services may include timekeeping information of varying accuracy within their signals. Timepieces with Bluetooth radio support, ranging from watches with basic control of functionality via a mobile app to full smartwatches[2] obtain time information from a connected phone, with no need to receive time signal broadcasts.

Single transmitter

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Radio clocks synchronized to a terrestrial time signal can usually achieve an accuracy within a hundredth of a second relative to the time standard,[1] generally limited by uncertainties and variability in radio propagation. Some timekeepers, particularly watches such as some Casio Wave Ceptors which are more likely than desk clocks to be used when travelling, can synchronise to any one of several different time signals transmitted in different regions.

Longwave and shortwave transmissions

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Radio clocks depend on coded time signals from radio stations. The stations vary in broadcast frequency, in geographic location, and in how the signal is modulated to identify the current time. In general, each station has its own format for the time code.

List of radio time signal stations

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List of radio time signal stations
Frequency Callsign Country Authority Location Aerial type Power Remarks
25 kHz RJH69   Belarus
VNIIFTRI
Vileyka
54°27′47″N 26°46′37″E / 54.46306°N 26.77694°E / 54.46306; 26.77694 (RJH69)
Triple umbrella antenna[a] 300 kW This is Beta time signal.[3] The signal is transmitted in non-overlapping time:
02:00–02:20 UTC RAB99
04:00–04:25 UTC RJH86
06:00–06:20 UTC RAB99
07:00–07:25 UTC RJH69
08:00–08:25 UTC RJH90
09:00–09:25 UTC RJH77
10:00–10:25 UTC RJH86
11:00–11:20 UTC RJH63
RJH77   Russia
VNIIFTRI
Arkhangelsk
64°21′29″N 41°33′58″E / 64.35806°N 41.56611°E / 64.35806; 41.56611 (RJH77)
Triple umbrella antenna[b] 300 kW
RJH63   Russia
VNIIFTRI
Krasnodar
44°46′25″N 39°32′50″E / 44.77361°N 39.54722°E / 44.77361; 39.54722 (RJH63)
Umbrella antenna[c] 300 kW
RJH90   Russia
VNIIFTRI
Nizhny Novgorod
56°10′20″N 43°55′38″E / 56.17222°N 43.92722°E / 56.17222; 43.92722 (RJH90)
Triple umbrella antenna[d] 300 kW
RJH86[3][e]   Kyrgyzstan
VNIIFTRI
Bishkek
43°02′29″N 73°37′09″E / 43.04139°N 73.61917°E / 43.04139; 73.61917 (RJH86)
Triple umbrella antenna[f] 300 kW
RAB99   Russia
VNIIFTRI
Khabarovsk
48°29′29″N 134°48′59″E / 48.49139°N 134.81639°E / 48.49139; 134.81639 (RAB99)
Umbrella antenna[g] 300 kW
40 kHz JJY   Japan
NICT
Mount Otakadoya, Fukushima
37°22′21″N 140°50′56″E / 37.37250°N 140.84889°E / 37.37250; 140.84889 (JJY)
Capacitance hat, height 250 m (820 ft) 50 kW Located near Fukushima[4]
50 kHz RTZ   Russia
VNIIFTRI
Irkutsk
52°25′41″N 103°41′12″E / 52.42806°N 103.68667°E / 52.42806; 103.68667 (RTZ)
Umbrella antenna 10 kW PM time code
60 kHz JJY   Japan
NICT
Mount Hagane, Kyushu
33°27′54″N 130°10′32″E / 33.46500°N 130.17556°E / 33.46500; 130.17556 (JJY)
Capacitance hat, height 200 m (660 ft) 50 kW Located on Kyūshū Island[4]
MSF   United Kingdom
NPL
Anthorn, Cumbria
54°54′27″N 03°16′24″W / 54.90750°N 3.27333°W / 54.90750; -3.27333 (MSF)[h]
Triple T-antenna[i] 17 kW Range up to 1,500 km (930 mi)
WWVB   United States
NIST
Near Fort Collins, Colorado[5]
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWVB)
Two capacitance hats, height 122 m (400 ft) 70 kW Received through most of mainland U.S.[4]
66.66 kHz RBU   Russia
VNIIFTRI
Taldom, Moscow
56°43′59″N 37°39′47″E / 56.73306°N 37.66306°E / 56.73306; 37.66306 (RBU)[j]
Umbrella antenna[k] 50 kW PM time code
68.5 kHz BPC   China
NTSC
Shangqiu, Henan
34°27′25″N 115°50′13″E / 34.45694°N 115.83694°E / 34.45694; 115.83694 (BPC)
4 guyed masts, arranged in a square 90 kW 21 hours per day, with a 3 hour break from 05:00–08:00 (China Standard Time) daily (21:00–24:00 UTC)[6]
75 kHz HBG   Switzerland
METAS
Prangins
46°24′24″N 06°15′04″E / 46.40667°N 6.25111°E / 46.40667; 6.25111 (HBG)
T-antenna[l] 20 kW Discontinued as of 1 January 2012
77.5 kHz DCF77   Germany
PTB
Mainflingen, Hessen
50°00′58″N 09°00′29″E / 50.01611°N 9.00806°E / 50.01611; 9.00806 (DCF77)
Vertical omni-directional antennas with top-loading capacity, height 150 metres (492')[7] 50 kW Located southeast of Frankfurt am Main with a range of up to 2,000 km (1,200 mi)[4][8]
BSF   Taiwan Zhongli
25°00′19″N 121°21′55″E / 25.00528°N 121.36528°E / 25.00528; 121.36528 (BSF)
T-antenna[m] [9]
100 kHz[n] BPL   China
NTSC
Pucheng, Shaanxi
34°56′56″N 109°32′35″E / 34.94889°N 109.54306°E / 34.94889; 109.54306 (BPL)
Single guyed lattice steel mast 800 kW Loran-C compatible format signal on air from 05:30 to 13:30 UTC,[10] with a reception radius up to 3,000 km (1,900 mi)[11]
RNS-E   Russia
VNIIFTRI
Bryansk
53°08′00″N 34°55′00″E / 53.13333°N 34.91667°E / 53.13333; 34.91667 (RNS-E)
5 guyed masts 800 kW CHAYKA compatible format signal[3]
04:00–10:00 UTC and 14:00–18:00 UTC
RNS-V   Russia
VNIIFTRI
Alexandrovsk-Sakhalinsky
51°05′00″N 142°43′00″E / 51.08333°N 142.71667°E / 51.08333; 142.71667 (RNS-V)
Single guyed mast 400 kW CHAYKA compatible format signal[3]
23:00–05:00 UTC and 11:00–17:00 UTC
129.1 kHz[o] DCF49   Germany
PTB
Mainflingen
50°00′58″N 09°00′29″E / 50.01611°N 9.00806°E / 50.01611; 9.00806 (DCF49)
T-antenna 100 kW EFR radio teleswitch[12]
time signal only (no reference frequency)
FSK ± 170 Hz 200 baud
135.6 kHz[o] HGA22   Hungary
PTB
Lakihegy
47°22′24″N 19°00′17″E / 47.37333°N 19.00472°E / 47.37333; 19.00472 (HGA22)
Single guyed mast 100 kW
139 kHz[o] DCF39   Germany
PTB
Burg bei Magdeburg
52°17′13″N 11°53′49″E / 52.28694°N 11.89694°E / 52.28694; 11.89694 (DCF39)
Single guyed mast 50 kW
162 kHz[p] ALS162   France
ANFR [fr]
Allouis
47°10′10″N 02°12′16″E / 47.16944°N 2.20444°E / 47.16944; 2.20444 (ALS162)
Two guyed steel lattice masts, height 350 m (1,150 ft), fed on the top 800 kW AM-broadcasting transmitter, located 150 km (93 mi) south of Paris with a range of up to 3,500 km (2,200 mi), using PM with encoding similar to DCF77[q]
198 kHz[p][r] BBC Radio 4   United Kingdom
NPL
Droitwich
52°17′44″N 2°06′23″W / 52.2955°N 2.1063°W / 52.2955; -2.1063 (BBC4)
T-aerial[s] 500 kW[13] Additional (50 kW) transmitters is at Burghead and Westerglen. The time signal is transmitted by 25 bit/s phase modulation.[14]
2.5 MHz BPM   China
NTSC
Pucheng, Shaanxi
34°56′56″N 109°32′35″E / 34.94889°N 109.54306°E / 34.94889; 109.54306 (BPM)
(BCD time code on 125 Hz sub-carrier not yet activated)

07:30–01:00 UTC[15]

WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 2.5 kW Binary-coded decimal (BCD) time code on 100 Hz sub-carrier
WWVH   United States
NIST
Kekaha, Hawaii
21°59′16″N 159°45′46″W / 21.98778°N 159.76278°W / 21.98778; -159.76278 (WWVH)
5 kW
3.33 MHz CHU   Canada
NRC
Ottawa, Ontario
45°17′40″N 75°45′27″W / 45.29444°N 75.75750°W / 45.29444; -75.75750 (CHU)
3 kW 300 baud Bell 103 time code
4.996 MHz RWM   Russia
VNIIFTRI
Taldom, Moscow
56°44′58″N 37°38′23″E / 56.74944°N 37.63972°E / 56.74944; 37.63972 (RWM)[j]
10 kW CW (1 Hz, 10 Hz)
5 MHz BPM   China
NTSC
Pucheng, Shaanxi
34°56′56″N 109°32′35″E / 34.94889°N 109.54306°E / 34.94889; 109.54306 (BPM)
BCD time code on 125 Hz sub-carrier.
00:00–24:00 UTC[15]
HLA   South Korea
KRISS
Daejeon
36°23′14″N 127°21′59″E / 36.38722°N 127.36639°E / 36.38722; 127.36639 (HLA)
2 kW
WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 10 kW[t] BCD time code on 100 Hz sub-carrier
WWVH   United States
NIST
Kekaha, Hawaii
21°59′16″N 159°45′46″W / 21.98778°N 159.76278°W / 21.98778; -159.76278 (WWVH)
10 kW
YVTO   Venezuela Caracas
10°30′13″N 66°55′44″W / 10.50361°N 66.92889°W / 10.50361; -66.92889 (YVTO)
1 kW
7.85 MHz CHU   Canada
NRC
Ottawa, Ontario
45°17′40″N 75°45′27″W / 45.29444°N 75.75750°W / 45.29444; -75.75750 (CHU)
10 kW 300 baud Bell 103 time code
9.996 MHz RWM   Russia
VNIIFTRI
Taldom, Moscow
56°44′58″N 37°38′23″E / 56.74944°N 37.63972°E / 56.74944; 37.63972 (RWM)[j]
10 kW CW (1 Hz, 10 Hz)
10 MHz BPM   China
NTSC
Pucheng, Shaanxi
34°56′56″N 109°32′35″E / 34.94889°N 109.54306°E / 34.94889; 109.54306 (BPM)
(BCD time code on 125 Hz sub-carrier not yet activated)
00:00–24:00 UTC[15]
LOL   Argentina
SHN
Buenos Aires[u] 2 kW Observatorio Naval Buenos Aires[16]
WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 10 kW BCD time code on 100 Hz sub-carrier
WWVH   United States
NIST
Kekaha, Hawaii
21°59′16″N 159°45′46″W / 21.98778°N 159.76278°W / 21.98778; -159.76278 (WWVH)
10 kW
PPE[17]   Brazil Rio de Janeiro, RJ 22°53′44″S 43°13′27″W / 22.89556°S 43.22417°W / -22.89556; -43.22417 (PPE)[17] Horizontal half-wavelength dipole[17] 1 kW[17] Maintained by National Observatory (Brazil)
14.67 MHz CHU   Canada
NRC
Ottawa, Ontario
45°17′40″N 75°45′27″W / 45.29444°N 75.75750°W / 45.29444; -75.75750 (CHU)
3 kW 300 baud Bell 103 time code
14.996 MHz RWM   Russia
VNIIFTRI
Taldom, Moscow
56°44′58″N 37°38′23″E / 56.74944°N 37.63972°E / 56.74944; 37.63972 (RWM)[j]
10 kW CW (1 Hz, 10 Hz)
15 MHz BPM   China
NTSC
Pucheng, Shaanxi
34°56′56″N 109°32′35″E / 34.94889°N 109.54306°E / 34.94889; 109.54306 (BPM)
(BCD time code on 125 Hz sub-carrier not yet activated)
01:00–09:00 UTC[15]
WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 10 kW BCD time code on 100 Hz sub-carrier
WWVH   United States
NIST
Kekaha, Hawaii
21°59′16″N 159°45′46″W / 21.98778°N 159.76278°W / 21.98778; -159.76278 (WWVH)
10 kW
20 MHz WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 2.5 kW BCD time code on 100 Hz sub-carrier
25 MHz WWV   United States
NIST
Near Fort Collins, Colorado
40°40′41″N 105°02′48″W / 40.67806°N 105.04667°W / 40.67806; -105.04667 (WWV)
Broadband monopole 2.0 kW Schedule: variable (experimental broadcast)
MIKES   Finland
MIKES
Espoo, Finland
60°10′49″N 24°49′35″E / 60.18028°N 24.82639°E / 60.18028; 24.82639 (MIKES time signal transmitter)
λ/4 sloper antenna 0.2 kW[18] 1 kHz amplitude modulation similar to DCF77.
As of 2017 the transmission is discontinued until further notice.[19]
"MIKES has a transmitter for time code and precise 25 MHz frequency for those near the Helsinki metropolitan area who need precise time and frequency."[20]

Descriptions

  1. ^ 3 umbrella antennas, fixed on 3 guyed tubular masts, insulated against ground with a height of 305 m (1,001 ft) and 15 guyed lattice masts with a height of 270 m (890 ft)
  2. ^ 3 umbrella antennas, fixed on 18 guyed lattice masts, height of central masts: 305 metres
  3. ^ umbrella antenna, fixed on 13 guyed lattice masts, height of central mast: 425 m (1,394 ft)
  4. ^ 3 umbrella antennas, fixed on 3 guyed tubular masts, insulated against ground with a height of 205 m (673 ft) and 15 guyed lattice masts with a height of 170 m (560 ft)
  5. ^ in air RJH66
  6. ^ 3 umbrella antennas, fixed on 18 guyed lattice masts, height of central masts: 276 m (906 ft)
  7. ^ umbrella antenna, fixed on 18 guyed lattice masts arranged in 3 rows, height of central masts: 238 m (781 ft)
  8. ^ Before 1 April 2007, the signal was transmitted from Rugby, Warwickshire 52°21′33″N 01°11′21″W / 52.35917°N 1.18917°W / 52.35917; -1.18917
  9. ^ 3 T-antennas, spun 150 m (490 ft) above ground between two 227 m (745 ft) high guyed grounded masts in a distance of 655 m (716 yd)
  10. ^ a b c d Before 2008, transmitter located at 55°44′14″N 38°09′04″E / 55.73722°N 38.15111°E / 55.73722; 38.15111
  11. ^ umbrella antenna, fixed on a 275 m (902 ft) high central tower insulated against ground and five 257 m (843 ft) high lattice masts insulated against ground in a distance of 324 metres (355 yards) from the central tower
  12. ^ T-antenna spun between two 125 m (410 ft) tall, grounded free-standing lattice towers in a distance of 227 m (248 yd)
  13. ^ T-antenna spun between two telecommunication towers in a distance of 33 m (36 yd)
  14. ^ Frequency for radio navigation system
  15. ^ a b c Frequency for radio teleswitch system
  16. ^ a b Frequency for AM-broadcasting
  17. ^ and requiring a more complex receiver for demodulating time signal
  18. ^ since 1988, before 200 kHz
  19. ^ Droitwich uses a T-aerial suspended between two 213 metres (699') guyed steel lattice radio masts, which stand 180 m (200 yd) apart.
  20. ^ Time signal article says 2.5 kW
  21. ^ [16] says that the transmitter is located in Observatorio Naval Buenos Aires at Avenida España 2099, Buenos Aires; on Google Street View, some antenna structures can be seen both on and near the building, however, it's unclear where exactly the specific antenna is located. The coordinates here point to the building itself. 34°37′19″S 58°21′18″W / 34.62194°S 58.35500°W / -34.62194; -58.35500 (LOL)
 
 
RJH69RJH6
/|
/|
/|
 
JH77RJH77
 
RJH63
 
← RJH90
 
RJH86
 
RAB99
 
RTZRT
 
MSF
 
 
↖︎RBURWM
 
BPC↗︎
 
↑ 
HBGHBG
 
|
|
|
|
DCF49, DCF77DCF49, DCF7
 
 
 
|
|
NS-ERNS-E
 
RNS-V
 
HGA22
 
DCF39
 
TDF↗︎
 
 
 
 
VTOYVTO
 
 
PEPPE
 
MIKESMIKE

Many other countries can receive these signals (JJY can sometimes be received in New Zealand, Western Australia, Tasmania, Southeast Asia, parts of Western Europe and the Pacific Northwest of North America at night), but success depends on the time of day, atmospheric conditions, and interference from intervening buildings. Reception is generally better if the clock is placed near a window facing the transmitter. There is also a propagation delay of approximately 1 ms for every 300 km (190 mi) the receiver is from the transmitter.

Clock receivers

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A number of manufacturers and retailers sell radio clocks that receive coded time signals from a radio station, which, in turn, derives the time from a true atomic clock.

One of the first radio clocks was offered by Heathkit in late 1983. Their model GC-1000 "Most Accurate Clock" received shortwave time signals from radio station WWV in Fort Collins, Colorado. It automatically switched between WWV's 5, 10, and 15 MHz frequencies to find the strongest signal as conditions changed through the day and year. It kept time during periods of poor reception with a quartz-crystal oscillator. This oscillator was disciplined, meaning that the microprocessor-based clock used the highly accurate time signal received from WWV to trim the crystal oscillator. The timekeeping between updates was thus considerably more accurate than the crystal alone could have achieved. Time down to the tenth of a second was shown on an LED display. The GC-1000 originally sold for US$250 in kit form and US$400 preassembled, and was considered impressive at the time. Heath Company was granted a patent for its design.[21][22]

By 1990, engineers from German watchmaker Junghans had miniaturized this technology to fit into the case of a digital wristwatch. The following year the analog version Junghans MEGA with hands was launched.

In the 2000s (decade) radio-based "atomic clocks" became common in retail stores; as of 2010 prices start at around US$15 in many countries.[23] Clocks may have other features such as indoor thermometers and weather station functionality. These use signals transmitted by the appropriate transmitter for the country in which they are to be used. Depending upon signal strength they may require placement in a location with a relatively unobstructed path to the transmitter and need fair to good atmospheric conditions to successfully update the time. Inexpensive clocks keep track of the time between updates, or in their absence, with a non-disciplined quartz-crystal clock, with the accuracy typical of non-radio-controlled quartz timepieces. Some clocks include indicators to alert users to possible inaccuracy when synchronization has not been recently successful.

The United States National Institute of Standards and Technology (NIST) has published guidelines recommending that radio clock movements keep time between synchronizations to within ±0.5 seconds to keep time correct when rounded to the nearest second.[24] Some of these movements can keep time between synchronizations to within ±0.2 seconds by synchronizing more than once spread over a day.[25]

Other broadcasts

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Attached to other broadcast stations
Broadcast stations in many countries have carriers precisely synchronized to a standard phase and frequency, such as the BBC Radio 4 longwave service on 198 kHz, and some also transmit sub-audible or even inaudible time-code information, like the Radio France longwave transmitter on 162 kHz. Attached time signal systems generally use audible tones or phase modulation of the carrier wave.
Teletext (TTX)
Digital text pages embedded in television video also provide accurate time. Many modern TV sets and VCRs with TTX decoders can obtain accurate time from Teletext and set the internal clock. However, the TTX time can vary up to 5 minutes.[26]

Many digital radio and digital television schemes also include provisions for time-code transmission.

Digital Terrestrial Television
The DVB and ATSC standards have 2 packet types that send time and date information to the receiver. Digital television systems can equal GPS stratum 2 accuracy (with short term clock discipline) and stratum 1 (with long term clock discipline) provided the transmitter site (or network) supports that level of functionality.
VHF FM Radio Data System (RDS)
RDS can send a clock signal with sub-second precision but with an accuracy no greater than 100 ms and with no indication of clock stratum. Not all RDS networks or stations using RDS send accurate time signals. The time stamp format for this technology is Modified Julian Date (MJD) plus UTC hours, UTC minutes and a local time offset.
L-band and VHF Digital Audio Broadcasting
DAB systems provide a time signal that has a precision equal to or better than Digital Radio Mondiale (DRM) but like FM RDS do not indicate clock stratum. DAB systems can equal GPS stratum 2 accuracy (short term clock discipline) and stratum 1 (long term clock discipline) provided the transmitter site (or network) supports that level of functionality. The time stamp format for this technology is BCD.
Digital Radio Mondiale (DRM)
DRM is able to send a clock signal, but one not as precise as navigation satellite clock signals. DRM timestamps received via shortwave (or multiple hop mediumwave) can be up to 200 ms off due to path delay. The time stamp format for this technology is BCD.
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Multiple transmitters

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A radio clock receiver may combine multiple time sources to improve its accuracy. This is what is done in satellite navigation systems such as the Global Positioning System. GPS, Galileo and GLONASS satellite navigation systems have one or more caesium, rubidium or hydrogen maser atomic clocks on each satellite, referenced to a clock or clocks on the ground. Dedicated timing receivers can serve as local time standards, with a precision better than 50 ns.[27][28][29][30] The recent revival and enhancement of LORAN, a land-based radio navigation system, will provide another multiple source time distribution system.

GPS clocks

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Many modern radio clocks use satellite navigation systems such as Global Positioning System to provide more accurate time than can be obtained from terrestrial radio stations. These GPS clocks combine time estimates from multiple satellite atomic clocks with error estimates maintained by a network of ground stations. Due to effects inherent in radio propagation and ionospheric spread and delay, GPS timing requires averaging of these phenomena over several periods. No GPS receiver directly computes time or frequency, rather they use GPS to discipline an oscillator that may range from a quartz crystal in a low-end navigation receiver, through oven-controlled crystal oscillators (OCXO) in specialized units, to atomic oscillators (rubidium) in some receivers used for synchronization in telecommunications. For this reason, these devices are technically referred to as GPS-disciplined oscillators.

GPS units intended primarily for time measurement as opposed to navigation can be set to assume the antenna position is fixed. In this mode, the device will average its position fixes. After approximately a day of operation, it will know its position to within a few meters. Once it has averaged its position, it can determine accurate time even if it can pick up signals from only one or two satellites.

GPS clocks provide the precise time needed for synchrophasor measurement of voltage and current on the commercial power grid to determine the health of the system.[31]

Astronomy timekeeping

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Although any satellite navigation receiver that is performing its primary navigational function must have an internal time reference accurate to a small fraction of a second, the displayed time is often not as precise as the internal clock. Most inexpensive navigation receivers have one CPU that is multitasking. The highest-priority task for the CPU is maintaining satellite lock—not updating the display. Multicore CPUs for navigation systems can only be found on high end products.

For serious precision timekeeping, a more specialized GPS device is needed. Some amateur astronomers, most notably those who time grazing lunar occultation events when the moon blocks the light from stars and planets, require the highest precision available for persons working outside large research institutions. The Web site of the International Occultation Timing Association[32] has detailed technical information about precision timekeeping for the amateur astronomer.

Daylight saving time

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Various formats listed above include a flag indicating the status of daylight saving time (DST) in the home country of the transmitter. This signal is typically used by clocks to adjust the displayed time to meet user expectations.

See also

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References

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  1. ^ a b Lombardi, Michael A. (March 2010). "How Accurate is a Radio Controlled Clock?" (PDF). Horological Journal. 152 (3): 108–111. Archived (PDF) from the original on 2021-01-07. Retrieved 2023-12-01 – via National Institute of Standards and Technology website.
  2. ^ "Bluetooth". Casio. Retrieved 16 July 2024.
  3. ^ a b c d Standard Time and Frequency Signals (PDF) (in Russian), retrieved 2018-07-15 — official signal specification.
  4. ^ a b c d Dennis D. McCarthy, P. Kenneth Seidelmann Time: From Earth Rotation to Atomic Physics Wiley-VCH, 2009 ISBN 3-527-40780-4 page 257
  5. ^ "NIST Radio Station WWVB". NIST. March 2010. Archived from the original on 25 March 2014. Retrieved 18 March 2014.
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