Do You Have the Time?

Horology is the science of time, timekeepers (clocks, watches) and timekeeping

Humans have been measuring time since the beginning of civilizations all over the world. There are almost as many calendars as there are major cultures in the world. Ever since world travel made the world a smaller place, there has been a need for international agreement as to how time is measured. Without a universally agreed upon measure of time, how can we coordinate our schedules with people in other parts of the country, or the world?

Back in 1878, Canadian Sir Sanford Fleming proposed the system of worldwide time zones that we still use today. He recommended that the world be divided into twenty-four time zones, each spaced 15 degrees of longitude apart. Since the earth rotates once every 24 hours and there are 360 degrees of longitude, each hour the earth rotates one-twenty-fourth of a circle or 15° of longitude. However, with the advent of technology and the Internet, there is a new push for a more standardized, absolute measure of time that would make time truly universal.

Atomic Time

With atomic time the unit of a second is defined as; the duration of 9,192,631,770 cycles of microwave light absorbed or emitted by the hyperfine transition of cesium-133 atoms in their ground state undisturbed by external fields. Pretty precise standards. In fact, it is the most accurate realization of a unit that mankind has yet achieved.

Today, cesium* clocks measure frequency with an accuracy of from 2 to 3 parts in 10 to the 14th, i.e. 0.00000000000002 Hz; this corresponds to a time measurement accuracy of 2 nanoseconds per day or one second in 1,400,000 years! A cesium clock operates by exposing cesium atoms to microwaves until they vibrate at one of their resonant frequencies and then counting the corresponding cycles as a measure of time. The frequency involved is that of the energy absorbed from the incident photons when they excite the outermost electron in a cesium atom to jump ("transition") from a lower to a higher orbit.

Where is it used...?

The National Institute of Standards and Technology (NIST) in Boulder, Colorado, as well as other International research laboratories maintain cesium clocks for scientific purposes. The U.S. Naval Observatory keeps track of Coordinated Universal Time (UTC) by using many atomic clocks and devices called "time-interval counters" that compare each clock's time against that of one "Master Clock," whose frequency is steered to match its time to the average of the other clocks.

Universal Time (UT) is counted from 0 hours at midnight, with unit of duration the mean solar day, defined to be as uniform as possible despite variations in the rotation of the Earth.

UT0 is the rotational time of a particular place of observation. It is observed as the diurnal motion of stars or extraterrestrial radio sources.

UT1 is computed by correcting UT0 for the effect of polar motion on the longitude of the observing site. It varies from uniformity because of the irregularities in the Earth's rotation.

Dynamical Time

Terrestrial Dynamical Time (TDT) views time from the earth's position and motion.

Terrestrial Time

Sometimes represented as (TT), or Terrestrial Dynamical Time, (TDT), with unit of duration 86400 SI seconds on the geoid, It was defined as being equal to TAI (Atomic time) plus 32.184 (atomic) seconds at the instant beginning 1 January 1977.

Barycentric Dynamical Time (TDB)

This is time at the center of mass of the solar system. TDB has various forms depending on the theory of relativity adopted.

Geocentric Coordinate Time (TCG)

is a coordinate time having its spatial origin at the center of mass of the Earth. TCG differs from TT as: TCG - TT = Lg x (JD -2443144.5) x 86400 seconds, with Lg = 6.969291e-10.

Barycentric Coordinate Time (TCB)

is a coordinate time having its spatial origin at the solar system barycenter (the center of the mass of our solar system). TCB differs from TDB in rate. The two are related by: TCB - TDB = iLb x (JD -2443144.5) x 86400 seconds, with Lb = 1.550505e-08.

Sidereal Time

Closely connected with the Mean Solar Time is the Sidereal Time, which is defined as the RA (Right Ascension) of the Local Meridian: when the Vernal Point passes the meridian it is 00:00 Sidereal Time.

Delta T is the difference between Earth rotational time (UT1) and dynamical time (TDT). Predicted values of UT1 - UTC are provided by the Earth Orientation Department.

Julian Day

Julian Day Number is a count of days elapsed since Greenwich mean noon on 1 January 4713 B.C., Julian proleptic (meaning the calender is being used for a time period before it actually was invented) calendar. The Julian Date is the Julian day number followed by the fraction of the day elapsed since the preceding noon.

Scientists and chronologists frequently make use of the Modified Julian Date (MJD), which is defined as MJD = JD - 2400000.5. An MJD day thus begins at midnight, civil date. Julian dates can be expressed in UT , TAI, TDT, etc. Julian dates are used primarily in scientific applications to measure elapsed time over periods of months and years, because the Gregorian Calendar continually reuses/repeats the same months every year and the calendar isn't a very accurate measure of time. Julian Date Numbers will also give you the exact hour of day because the numbers are expressed as a whole number and a fraction (the numbers after the decimal) of a day.

Military Time

A system of time that may seem more familiar and mundane, compared to the other methods of precision timekeeping mentioned above, is based on the number of hours in a day - 24. Each hour is numbered from one to 24, starting at midnight (labeled 00:00 hours) and numbered consecutively as the day progresses towards midnight the following night. For example, 5:00am in the morning is 05:00 hours. 5:00pm in the evening, however, is easily distinguished from morning as 17:00 hours - the 17th hour of the day (see the table at left