Hours to Seconds (h to s)

The hour (h) is exactly 3600 seconds (60 minutes × 60 seconds) by SI definition, derived from the Babylonian-Egyptian sexagesimal time-division system preserved unchanged into the modern SI second. The recognised symbol is "h" (lowercase) under ISO 80000-3 conventions, with "hr" appearing in some casual writing as a non-standard variant. The hour is not part of the SI base units but is recognised by NIST and BIPM as a non-SI unit accepted for use with the SI. The relationship to the second is exact (1 h = 3600 s), to the minute is exact (1 h = 60 min), and to the day is exact (1 day = 24 h). Sub-hour precision uses minutes and seconds; super-hour precision uses days, weeks, months and years. The hour is universally used across every modern timekeeping context globally.

The hour as a unit of time has been preserved unchanged from ancient Egyptian and Babylonian astronomy, where the day was first divided into 24 hours (12 daylight hours and 12 nighttime hours) by ancient Egyptian astronomy in the second millennium BC. The 24-hour day was preserved through Greek and Roman astronomy and into the modern SI time-system without modification. The unit's name derives from the Greek "hora" (season, time of day, hour). Like the minute, the hour is not part of the SI base units but is recognised by NIST and BIPM as a non-SI unit accepted for use with the SI in everyday-time-keeping, transportation, employment-and-payroll, and engineering contexts. The 1967 SI second-definition transitively defined the hour as exactly 3600 seconds (60 minutes × 60 seconds), fixed by the atomic-clock primary standard. ISO 80000-3 specifies seconds as the SI-canonical primary time unit but tolerates hours in commercial-and-everyday timekeeping contexts. The hour is universally used across timekeeping, transportation-scheduling, employment-and-payroll wage-rate specifications, and engineering-process documentation.

Everyday timekeeping: every clock, watch, smartphone, and digital display denominates time-of-day in hours alongside minutes. The 12-hour AM/PM format is dominant in US-customary timekeeping; the 24-hour format is dominant in EU-jurisdiction and most non-US timekeeping. Both express the same underlying SI hour. Transportation scheduling: every flight schedule, train timetable, ship-arrival notification, and bus schedule denominates time in hours-and-minutes format for the consumer-facing schedule display. Aviation universally uses 24-hour format (UTC for international flights, local-time for domestic); rail timetables in the EU use 24-hour format; US domestic transportation typically uses 12-hour AM/PM format. Employment and payroll: hourly wage rates (US-jurisdiction federal minimum wage at $7.25/hour, UK National Living Wage at £11.44/hour for 21+ in 2024, various state and EU national minimum-wage figures) universally use hours as the wage-rate denominator. Salary-equivalent annual figures translate from per-hour wages times typical 2080 working hours per year. Engineering and process specifications: industrial-process throughput rates, vehicle-fuel-economy figures (mpg in US, l/100km in EU, with both reflecting fuel-per-distance over operational hours), HVAC capacity ratings (BTU/h, kW), and electricity-billing units (kWh) all use hours as the time denominator.

The second (s) is the SI base unit of time, defined since 1967 as exactly 9,192,631,770 periods of the radiation corresponding to the transition between the two hyperfine levels of the ground state of the caesium-133 atom (the Cs-133 hyperfine transition at 9.192631770 GHz). The 2019 SI redefinition preserved this atomic-clock definition. The recognised SI symbol is "s" (lowercase, italics-disambiguated when needed). The second is the foundational unit for all other SI time-related units (the hertz at 1/s, the becquerel at 1/s for radioactive decay, the SI joule via 1 J = 1 N·m and the metre is defined via the speed of light × the second). Atomic clocks based on the caesium-133 transition currently achieve precision better than 1 part in 10^15, with the most-recent optical-lattice atomic clocks (Sr-87, Yb-171) approaching 1 part in 10^18 precision. The second is preserved unchanged across every modern timekeeping context, scientific publication, and engineering specification.

The second has been preserved unchanged in concept since Babylonian astronomy in the third millennium BC, where the day was divided into 24 hours, each hour into 60 minutes, and each minute into 60 seconds — the sexagesimal time-division system that survives globally today. The modern SI second was redefined in atomic terms at the 13th CGPM in 1967 as "the duration of 9,192,631,770 periods of the radiation corresponding to the transition between the two hyperfine levels of the ground state of the caesium-133 atom" at zero magnetic field and at rest at 0 K. The atomic-second definition replaced the older astronomical-second definition (1/86,400 of a mean solar day, since 1820) which was based on Earth's rotation rate and therefore subject to the slow secular slowdown of Earth's rotation due to tidal friction. The 2019 SI redefinition preserved the atomic-second definition as the fundamental SI base unit of time, with all other SI units (metre, kilogram, ampere, kelvin, mole, candela) anchored to defined fundamental constants traceable through the second. The second is the SI base unit of time and the universal primary unit across physics, engineering, atomic-clock metrology, GPS, and modern timekeeping.

Atomic-clock metrology and GPS: every modern atomic clock (caesium-fountain primary clocks at NIST, NPL, PTB, NMIJ; optical-lattice clocks at JILA, Riken, NPL) measures time in seconds with precision better than 1 part in 10^15. GPS satellites carry caesium and rubidium atomic clocks for nanosecond-precision timing, with the GPS-time-system traceable to UTC (Coordinated Universal Time) maintained by atomic clocks at BIPM in Paris. Physics-laboratory and engineering measurement: every modern physics-laboratory measurement involving time denominates in seconds for the SI-canonical primary documentation. Particle-physics decay-rate measurements, fluid-dynamics oscillation-period analysis, mechanical-engineering vibration-period analysis, and atomic-physics-spectroscopy lifetime measurements all use seconds. Sports timing and athletic-record certification: every IAAF-sanctioned (now World Athletics) athletics-meet timing system (Hamamatsu Photonics, Omega Timekeeping, Seiko Sports Timing) measures sport-event times in seconds with millisecond precision (Usain Bolt 100m world record 9.58 s; Eliud Kipchoge marathon world record 2:01:09 = 7269 s). Computing and electronics: every modern computer-system clock denominates time in seconds and sub-second multiples (clock cycles at GHz = billion-per-second, system-time in nanoseconds for high-precision events, kernel-time in microseconds for OS scheduling). Sub-second precision is universally required across modern computing systems.