A water clock or clepsydra (from Ancient Greek κλεψύδρα (klepsúdra) 'pipette, water clock'; from κλέπτω (kléptō) 'to steal' and ὕδωρ (hydor) 'water'; lit. ' water thief') is a timepiece by which time is measured by the regulated flow of liquid into (inflow type) or out from (outflow type) a vessel, and where the amount of liquid can then be measured.
Water clocks are one of the oldest time-measuring instruments. The simplest form of water clock, with a bowl-shaped outflow, existed in Babylon, Egypt, and Persia around the 16th century BC. Other regions of the world, including India and China, also provide early evidence of water clocks, but the earliest dates are less certain. Water clocks were used in ancient Greece and in ancient Rome, as described by technical writers such as Ctesibius (died 222 BC) and Vitruvius (died after 15 BC).
Designs
A water clock uses the flow of water to measure time. If viscosity is neglected, the physical principle required to study such clocks is Torricelli's law. Two types of water clock exist: inflow and outflow. In an outflow water clock, a container is filled with water, and the water is drained slowly and evenly out of the container. This container has markings that are used to show the passage of time. As the water leaves the container, an observer can see where the water is level with the lines and tell how much time has passed. An inflow water clock works in basically the same way, except instead of flowing out of the container, the water is filling up the marked container. As the container fills, the observer can see where the water meets the lines and tell how much time has passed. Some modern timepieces are called "water clocks" but work differently from the ancient ones. Their timekeeping is governed by a pendulum, but they use water for other purposes, such as providing the power needed to drive the clock by using a water wheel or something similar, or by having water in their displays.
The Greeks and Romans advanced water clock design to include the inflow clepsydra with an early feedback system, gearing, and escapement mechanism, which were connected to fanciful automata and resulted in improved accuracy. Further advances were made in Byzantium, Syria, and Mesopotamia, where increasingly accurate water clocks incorporated complex segmental and epicyclic gearing, water wheels, and programmability, advances which eventually made their way to Europe. Independently, the Chinese developed their own advanced water clocks, incorporating gears, escapement mechanisms, and water wheels, passing their ideas on to Korea and Japan.
Some water clock designs were developed independently, and some knowledge was transferred through the spread of trade. These early water clocks were calibrated with a sundial. While never reaching a level of accuracy comparable to today's standards of timekeeping, the water clock was a commonly used timekeeping device for millennia, until it was replaced by more accurate verge escapement mechanical clocks in Europe around 1300.
Regional development
Egypt
The oldest water clock of which there is physical evidence dates to c. 1417–1379 BC in the New Kingdom of Egypt, during the reign of the pharaoh Amenhotep III, where it was used in the Precinct of Amun-Re at Karnak. The oldest documentation of the water clock is the tomb inscription of the 16th century BC Egyptian court official Amenemhet, which identifies him as its inventor. These simple water clocks, which were of the outflow type, were stone vessels with sloping sides that allowed water to drip at a nearly constant rate from a small hole near the bottom. There were twelve separate columns with consistently spaced markings on the inside to measure the passage of "hours" as the water level reached them. The columns were for each of the twelve months to allow for the variations of the seasonal hours. Priests used these clocks to determine the time at night so that the temple rites and sacrifices could be performed at the correct hour.
Babylon
Clay tablet | |
---|---|
Water clock calculations by Nabû-apla-iddina. | |
Size | H:8.2 cm (3.2 in) W:11.8 cm (4.6 in) D:2.5 cm (0.98 in) |
Writing | cuneiform, Akkadian |
Created | 600BC-500BC |
Present location | Room 55, British Museum |
Identification | 29371 |
In Babylon, water clocks were of the outflow type and were cylindrical in shape. Use of the water clock as an aid to astronomical calculations dates back to the Old Babylonian Empire (c. 2000 – c. 1600 BC). While there are no surviving water clocks from the Mesopotamian region, most evidence of their existence comes from writings on clay tablets. Two collections of tablets, for example, are the Enuma Anu Enlil (1600–1200 BC) and the MUL.APIN (7th century BC). In these tablets, water clocks are used for payment of the night and day watches (guards).
These clocks were unique, as they did not have an indicator such as hands (as are typically used today) or grooved notches (as were used in Egypt). Instead, these clocks measured time "by the weight of water flowing from" it. The volume was measured in capacity units called qa. The weight, mana or mina (the Greek unit for about one pound), is the weight of water in a water clock.
In Babylonian times, time was measured with temporal hours. So, as seasons changed, so did the length of a day. "To define the length of a 'night watch' at the summer solstice, one had to pour two mana of water into a cylindrical clepsydra; its emptying indicated the end of the watch. One-sixth of mana had to be added each succeeding half-month. At the equinox, three mana had to be emptied in order to correspond to one watch, and four mana was emptied for each watch of the winter solstitial night."
India
Main article: Hindu units of timeN. Narahari Achar and Subhash Kak suggest that water clocks were used in ancient India as early as the 2nd millennium BC, based on their appearance in the Atharvaveda'. According to N. Kameswara Rao, pots excavated from the Indus Valley Civilisation site of Mohenjo-daro may have been used as water clocks. They are tapered at the bottom, have a hole on the side, and are similar to the utensil used to perform abhiṣeka (ritual water pouring) on lingams.
The Jyotisha, one of the six Vedanga disciplines, describes water clocks called ghati or kapala that measure time in units of nadika (around 24 minutes). A clepsydra in the form of a floating and sinking copper vessel is mentioned in the Sürya Siddhānta (5th century AD). At Nalanda mahavihara, an ancient Buddhist university, four-hour intervals were measured by a water clock, which consisted of a similar copper bowl holding two large floats in a larger bowl filled with water. The bowl was filled with water from a small hole at its bottom; it sank when filled and was marked by the beating of a drum in the daytime. The amount of water added varied with the seasons, and students at the university operated the clock.
Descriptions of similar water clocks are also given in the Pañca Siddhāntikā by the polymath Varāhamihira in the 6th century, which adds further detail to the account given in the Sūrya Siddhānta. Further descriptions are recorded in the Brāhmasphuṭasiddhānta by the mathematician Brahmagupta in the 7th century. A detailed description with measurements is also recorded by the astronomer Lalla in the 8th century, who describes the ghati as a hemispherical copper vessel with a hole that is fully filled after one nadika.
China
In ancient China, as well as throughout East Asia, water clocks were very important in the study of astronomy and astrology. The oldest written reference dates the use of the water clock in China to the 6th century BC. From about 200 BC onwards, the outflow clepsydra was replaced almost everywhere in China by the inflow type with an indicator-rod borne on a float(called fou chien lou,浮箭漏). The Han dynasty philosopher and politician Huan Tan (40 BC – AD 30), a Secretary at the Court in charge of clepsydrae, wrote that he had to compare clepsydrae with sundials because of how temperature and humidity affected their accuracy, demonstrating that the effects of evaporation, as well as of temperature on the speed at which water flows, were known at this time. The liquid in water clocks was liable to freezing, and had to be kept warm with torches, a problem that was solved in 976 by the Chinese astronomer and engineer Zhang Sixun. His invention—a considerable improvement on Yi Xing's clock—used mercury instead of water. Mercury is a liquid at room temperature, and freezes at −38.83 °C (−37.9 °F), lower than any air temperature common outside polar regions. Again, instead of using water, the early Ming Dynasty engineer Zhan Xiyuan (c. 1360–1380) created a sand-driven wheel clock, improved upon by Zhou Shuxue (c. 1530–1558).
The use of clepsydrae to drive mechanisms illustrating astronomical phenomena began with the Han Dynasty polymath Zhang Heng (78–139) in 117, who also employed a waterwheel. Zhang Heng was the first in China to add an extra compensating tank between the reservoir and the inflow vessel, which solved the problem of the falling pressure head in the reservoir tank. Zhang's ingenuity led to the creation by the Tang dynasty mathematician and engineer Yi Xing (683–727) and Liang Lingzan in 725 of a clock driven by a waterwheel linkwork escapement mechanism. The same mechanism would be used by the Song dynasty polymath Su Song (1020–1101) in 1088 to power his astronomical clock tower, as well as a chain drive. Su Song's clock tower, over 30 feet (9.1 m) tall, possessed a bronze power-driven armillary sphere for observations, an automatically rotating celestial globe, and five front panels with doors that permitted the viewing of changing mannequins which rang bells or gongs, and held tablets indicating the hour or other special times of the day. In the 2000s, in Beijing's Drum Tower an outflow clepsydra is operational and displayed for tourists. It is connected to automata so that every quarter-hour a small brass statue of a man claps his cymbals.
Persia
The use of water clocks in Greater Iran, especially in the desert areas such as Yazd, Isfahan, Zibad, and Gonabad, dates back to 500 BC. Later, they were also used to determine the exact holy days of pre-Islamic religions such as Nowruz (March equinox), Mehregan (September equinox), Tirgan (summer solstice) and Yaldā Night (winter solstice) – the shortest, longest, and equal-length days and nights of the years. The water clocks, called pengan (and later fenjan) used were one of the most practical ancient tools for timing the yearly calendar. The water clock was the most accurate and commonly used timekeeping device for calculating the amount or the time that a farmer must take water from a qanat or well for irrigation until more accurate current clocks replaced it.
Persian water clocks were a practical, useful, and necessary tool for the qanat's shareholders to calculate the length of time they could divert water to their farms or gardens. The qanat was the only water source for agriculture and irrigation in arid area so a just and fair water distribution was very important. Therefore, a very fair and clever old person was elected to be the manager of the water clock or mir āb, and at least two full-time managers were needed to control and observe the number of hours and announce the exact time of the days and nights from sunrise to sunset because shareholders usually divided between day and night owners.
The Persian water clock consisted of a large pot full of water and a bowl with a small hole in the center. When the bowl became full of water, it would sink into the pot, and the manager would empty the bowl and again put it on the top of the water in the pot. He would record the number of times the bowl sank by putting small stones into a jar. The place where the clock was situated and its managers were collectively known as the khane pengān. Usually this would be the top floor of a public house, with west- and east-facing windows to show the time of sunset and sunrise. The Zibad water clock was in use until 1965, when it was replaced by modern clocks.
Greco-Roman world
The word "clepsydra" comes from the Greek meaning "water thief". The Greeks considerably advanced the water clock by tackling the problem of the diminishing flow. They introduced several types of the inflow clepsydra, one of which included the earliest feedback control system. Ctesibius invented an indicator system typical for later clocks such as the dial and pointer. The Roman engineer Vitruvius described early alarm clocks, working with gongs or trumpets. A commonly used water clock was the simple outflow clepsydra. This small earthenware vessel had a hole in its side near the base. In both Greek and Roman times, this type of clepsydra was used in courts for allocating periods of time to speakers. In important cases, such as when a person's life was at stake, it was filled completely, but for more minor cases, only partially. If proceedings were interrupted for any reason, such as to examine documents, the hole in the clepsydra was stopped with wax until the speaker was able to resume his pleading.
Clepsydrae for keeping time
Some scholars suspect that the clepsydra may have been used as a stop-watch for imposing a time limit on clients' visits in Athenian brothels. Slightly later, in the early 3rd century BC, the Hellenistic physician Herophilos employed a portable clepsydra on his house visits in Alexandria for measuring his patients' pulse-beats. By comparing the rate by age group with empirically obtained data sets, he was able to determine the intensity of the disorder.
Between 270 BC and AD 500, Hellenistic (Ctesibius, Hero of Alexandria, Archimedes) and Roman horologists and astronomers were developing more elaborate mechanized water clocks. The added complexity was aimed at regulating the flow and at providing fancier displays of the passage of time. For example, some water clocks rang bells and gongs, while others opened doors and windows to show figurines of people, or moved pointers, and dials. Some even displayed astrological models of the universe. The 3rd century BC engineer Philo of Byzantium referred in his works to water clocks already fitted with an escapement mechanism, the earliest known of its kind.
The biggest achievement of the invention of clepsydrae during this time, however, was by Ctesibius with his incorporation of gears and a dial indicator to automatically show the time as the lengths of the days changed throughout the year, because of the temporal timekeeping used during his day. Also, a Greek astronomer, Andronicus of Cyrrhus, supervised the construction of his Horologion, known today as the Tower of the Winds, in the Athens marketplace (or agora) in the first half of the 1st century BC. This octagonal clocktower showed scholars and shoppers both sundials and a windvane. Inside it was a mechanized clepsydra, although the type of display it used cannot be known for sure; some possibilities are: a rod that moved up and down to display the time, a water-powered automaton that struck a bell to mark the hours, or a moving star disk in the ceiling.
Medieval Islamic world
In the medieval Islamic world (632-1280), the use of water clocks has its roots from Archimedes during the rise of Alexandria in Egypt and continues on through Byzantium. The water clocks by the Arabic engineer Al-Jazari, however, are credited for going "well beyond anything" that had preceded them. In Al-Jazari's 1206 treatise, he describes one of his water clocks, the elephant clock. The clock recorded the passage of temporal hours, which meant that the rate of flow had to be changed daily to match the uneven length of days throughout the year. To accomplish this, the clock had two tanks, the top tank was connected to the time indicating mechanisms and the bottom was connected to the flow control regulator. Basically, at daybreak, the tap was opened and water flowed from the top tank to the bottom tank via a float regulator that maintained a constant pressure in the receiving tank.
The most sophisticated water-powered astronomical clock was Al-Jazari's castle clock, considered by some to be an early example of a programmable analog computer, in 1206. It was a complex device that was about 11 feet (3.4 m) high, and had multiple functions alongside timekeeping. It included a display of the zodiac and the solar and lunar orbits, and a pointer in the shape of the crescent moon which traveled across the top of a gateway, moved by a hidden cart and causing automatic doors to open, each revealing a mannequin, every hour. It was possible to re-program the length of day and night in order to account for the changing lengths of day and night throughout the year, and it also featured five musician automata who automatically play music when moved by levers operated by a hidden camshaft attached to a water wheel. Other components of the castle clock included a main reservoir with a float, a float chamber and flow regulator, plate and valve trough, two pulleys, crescent disc displaying the zodiac, and two falcon automata dropping balls into vases.
The first water clocks to employ complex segmental and epicyclic gearing was invented earlier by the Arab engineer Ibn Khalaf al-Muradi in Islamic Iberia c. 1000. His water clocks were driven by water wheels, as was also the case for several Chinese water clocks in the 11th century. Comparable water clocks were built in Damascus and Fez. The latter (Dar al-Magana) remains until today and its mechanism has been reconstructed. The first European clock to employ these complex gears was the astronomical clock created by Giovanni de Dondi in c. 1365. Like the Chinese, Arab engineers at the time also developed an escapement mechanism which they employed in some of their water clocks. The escapement mechanism was in the form of a constant-head system, while heavy floats were used as weights.
Korea
Main article: Jang Yeong-sil § Water ClockIn 718, Unified Silla established the system of clepsydra for the first time in Korean history, imitating the Tang Dynasty. In 1434, during Joseon rule, Jang Yeong-sil (Korean: 장영실; Hanja: 蔣英實), a palace guard and later chief court engineer, constructed the Borugak Jagyeongnu or self-striking water clock of Borugak Pavillion for Sejong the Great.
What made his water clock self-striking (or automatic) was using jack-work mechanisms: three wooden figures or "jacks" struck objects to signal the time. This innovation no longer required the reliance of human workers, known as "rooster men", to constantly replenish it.
The uniqueness of the clock was its capability to announce dual-times automatically with visual and audible signals. Jang developed a signal conversion technique that made it possible to measure analog time and announce digital time simultaneously as well as to separate the water mechanisms from the ball-operated striking mechanisms. The conversion device was called pangmok, and was placed above the inflow vessel that measured the time, the first device of its kind in the world. Thus, the Borugak water clock is the first hydro-mechanically engineered dual-time clock in the history of horology.
Japan
Emperor Tenji made Japan's first water clock called a Rokoku (漏刻). They were highly socially significant and run by Doctors of Water Clock [ja]
Temperature, water viscosity, and clock accuracy
When viscosity can be neglected, the outflow rate of the water is governed by Torricelli's law, or more generally, by Bernoulli's principle. Viscosity will dominate the outflow rate if the water flows out through a nozzle that is sufficiently long and thin, as given by the Hagen–Poiseuille equation. Approximately, the flow rate is for such design inversely proportional to the viscosity, which depends on the temperature. Liquids generally become less viscous as the temperature increases. In the case of water, the viscosity varies by a factor of about seven between zero and 100 degrees Celsius. Thus, a water clock with such a nozzle would run about seven times faster at 100 °C than at 0 °C. Water is about 25 percent more viscous at 20 °C than at 30 °C, and a variation in temperature of one degree Celsius, in this "room temperature" range, produces a change of viscosity of about two percent. Therefore, a water clock with such a nozzle that keeps good time at some given temperature would gain or lose about half an hour per day if it were one degree Celsius warmer or cooler. To make it keep time within one minute per day would require its temperature to be controlled within 1⁄30°C (about 1⁄17°F). There is no evidence that this was done in antiquity, so ancient water clocks with sufficiently thin and long nozzles (unlike the modern pendulum-controlled one described above) cannot have been reliably accurate by modern standards. However, while modern timepieces may not be reset for long periods, water clocks were likely reset every day, when refilled, based on a sundial, so the cumulative error would not have been great.
See also
Notes
- Turner 1984, p. 1
- Mills, A. A. (August 1982). "Newton's Water Clocks and the Fluid Mechanics of Clepsydrae". Notes and Records of the Royal Society of London. 37 (1): 35–61. doi:10.1098/rsnr.1982.0004. JSTOR 531476. Retrieved 18 June 2024.
- ^ Cotterell & Kamminga 1990, pp. 59–61.
- Berlev, Oleg (1997). "Bureaucrats". In Donadoni, Sergio (ed.). The Egyptians. Trans. Bianchi, Robert et al. Chicago: The University of Chicago Press. p. 118. ISBN 0-226-15555-2.
- Cotterell & Kamminga 1990
- Pingree, David (1998). "Legacies in Astronomy and Celestial Omens". In Stephanie Dalley (ed.). The Legacy of Mesopotamia. Oxford: Oxford University Press. pp. 125–126. ISBN 0-19-814946-8.
- Evans, James (1998). The History and Practice of Ancient Astronomy. Oxford: Oxford University Press. p. 15. ISBN 0-19-509539-1.
- Neugebauer 1947.
- ^ Neugebauer 1947, pp. 39–40
- Achar, N. Narahari (December 1998). "On the meaning of AV XIX. 53.3: Measurement of Time?". Electronic Journal of Vedic Studies. Archived from the original on 2015-09-23. Retrieved 2007-05-11.
- Kak, Subhash (2003-02-17). "Babylonian and Indian Astronomy: Early Connections". In Pande, G. C. (ed.). History of Science, Philosophy & Culture in Indian Civilization. Vol. 1 Part 4. pp. 847–869. arXiv:physics/0301078. Bibcode:2003physics...1078K.
- Rao, N. Kameswara (December 2005). "Aspects of prehistoric astronomy in India" (PDF). Bulletin of the Astronomical Society of India. 33 (4): 499–511. Bibcode:2005BASI...33..499R. Retrieved 2007-05-11.
It appears that two artifacts from Mohenjo-daro and Harappa might correspond to these two instruments. Joshi and Parpola (1987) lists a few pots tapered at the bottom and having a hole on the side from the excavations at Mohenjadaro (Figure 3). A pot with a small hole to drain the water is very similar to clepsydras described by Ohashi to measure the time (similar to the utensil used over the lingum in Shiva temple for abhishekam).
- "A copper vessel (in the shape of the lower half of the water jar) which has a small hole in its bottom and being placed upon clean water in a basin sinks exactly 60 times in a day and at night." – Chapter 13, verse 23 of the Sürya Siddhānta.
- Scharfe, Hartmut (2002). Education in Ancient India. Leiden: Brill Academic Publishers. p. 171. ISBN 90-04-12556-6.
- "A copper vessel weighing 10 palas, 6 angulas in height and twice as much in breadth at the mouth—this vessel of the capacity of 60 palas of water and hemispherical in form is called a ghati." This copper vessel, which was bored with a needle and made of 3 1/8 masas of gold and 4 angulas long, gets filled in one nadika."
- ^ Needham 2000, p. 479
- Needham 1995, pp. 321–322
- Temple 1986, p. 107.
- Mercury at the Encyclopædia Britannica
- Needham 1986, pp. 510–511
- Needham 2000, pp. 30, 532
- Needham 2000, pp. 471, 490, 532
- Needham 2000, p. 462
- Ellywa (1 August 2007). "Clepsydra in the Drum Tower, Beijing, China" – via Wikimedia Commons.
- Rahimi, G.H. "Water Sharing Management in Ancient Iran, with Special Reference to Pangān (cup) in Iran" (PDF). Tehran university science magazine.
- ^ "Conference of Qanat in Iran – water clock in Persia 1383". www.aftabir.com (in Persian).
- ^ "Qanat is cultural and social and scientific heritage in Iran".
- "Water clock or Pengan in Iran, National conference 2004 Gonabad". parssea.org. Archived from the original on 2017-06-10.
- vista.ir. "Qanat iscultural and social and scientific heritage in Iran".
- ^ "water clock in persia". amordadnews.com. Archived from the original on 2014-04-29.
- This engraving is taken from "Rees's Clocks, Watches, and Chronometers 1819–20. The design of the illustration was modified from Claude Perrault's illustrations in his 1684 translation of Vitruvius's Les Dix Livres d'Architecture (1st century BC), of which he describes Ctesibius's clepsydra in great length.
- Levy, Janey (2004). Keeping Time Through the Ages: The History of Tools Used to Measure Time. Rosen Classroom. p. 11. ISBN 9780823989171.
The Greeks named the water clock 'clepsydra' (KLEP-suh-druh), which means 'water thief'.
- Goodenow, Orr & Ross (2007), p. 7
- ^ John G. Landels: "Water-Clocks and Time Measurement in Classical Antiquity", "Endeavour", Vol. 3, No. 1 (1979), pp. 32–37 (35)
- Hill 1981, p. 6
- ^ Landels, John G. (1979). "Water-Clocks and Time Measurement in Classical Antiquity". Endeavour. 3 (1): 33. doi:10.1016/0160-9327(79)90007-3.
- Lewis 2000, pp. 356f.
- Noble, Joseph V.; de Solla Price, Derek (October 1968). "The Water Clock in the Tower of the Winds". American Journal of Archaeology. 72 (4): 345–355. doi:10.2307/503828. JSTOR 503828. Retrieved 19 June 2024.
- ibn al-Razzaz al-Jazari (1974). The Book of Knowledge of Ingenious Mechanical Devices. Translated and annotated by Donald Routledge Hill. Dordrecht: D. Reidel. ISBN 969-8016-25-2.
- al-Hassan & Hill 1986, pp. 57–59
- ^ "Ancient Discoveries, Episode 11: Ancient Robots". History Channel. Archived from the original on March 1, 2014. Retrieved 2008-09-06.
- Howard R. Turner (1997), Science in Medieval Islam: An Illustrated Introduction, p. 184. University of Texas Press, ISBN 0-292-78149-0.
- Routledge Hill, Donald, "Mechanical Engineering in the Medieval Near East", Scientific American, May 1991, pp. 64–69. (cf. Donald Routledge Hill, Mechanical Engineering Archived 2007-12-25 at the Wayback Machine)
- "two falcon automata dropping balls into vases – Google Search". www.google.com.my.
- ^ Hassan, Ahmad Y, Transfer Of Islamic Technology To The West, Part II: Transmission Of Islamic Engineering, History of Science and Technology in Islam
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- Koetsier, Teun; ceccarelli, marco (5 April 2012). Explorations in the History of Machines and Mechanisms: Proceedings of HMM2012. Springer Science & Business Media. p. 90. ISBN 9789400741324. Retrieved 27 March 2017.
- Koetsier, Teun; ceccarelli, marco (5 April 2012). Explorations in the History of Machines and Mechanisms: Proceedings of HMM2012. Springer Science & Business Media. p. 95. ISBN 9789400741324. Retrieved 27 March 2017.
- Fifty Wonders of Korea - Vol. 2. KSCPP. Archived from the original on 2017-03-27. Retrieved 27 March 2017.
- Ceccarelli, Marco (21 May 2014). Distinguished Figures in Mechanism and Machine Science: Their Contributions and Legacies. Springer. p. 111. ISBN 9789401789479. Retrieved 27 March 2017.
- Pisano, Raffaele (30 June 2015). A Bridge between Conceptual Frameworks: Sciences, Society and Technology Studies. Springer. p. 364. ISBN 9789401796453. Retrieved 27 March 2017.
- Goodenow, Orr & Ross (2007), p. 6
- CRC Handbook of Chemistry and Physics, page F-36
Sources used
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- Cowan, Harrison J. (1958). Time and Its Measurement: From the stone age to the nuclear age. Ohio: The World Publishing Company. Bibcode:1958tmfs.book.....C.
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- Hill, D.R. (1981). Arabic Water–Clocks. Syria: University of Aleppo.
- Lewis, Michael (2000). "Theoretical Hydraulics, Automata, and Water Clocks". In Wikander, Örjan (ed.). Handbook of Ancient Water Technology. Technology and Change in History. Vol. 2. Leiden. pp. 343–369 (356f.). ISBN 90-04-11123-9.
{{cite book}}
: CS1 maint: location missing publisher (link) - Needham, Joseph (1986). Science & Civilization in China: Volume 4, Physics and Physical Technology, Part 2, Mechanical Engineering. Taipei: Caves Books.
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- Needham, Joseph (2000). Science & Civilisation in China: Volume 4, Physics and Physical Technology, Part 2, Mechanical Engineering. Cambridge University Press. ISBN 0-521-05803-1. OCLC 153247141.
- Neugebauer, Otto (1947). "Studies in Ancient Astronomy. VIII. The Water Clock in Babylonian Astronomy". Isis. 37 (1/2): 37–43. doi:10.1086/347965. PMID 20247883. S2CID 120229480. (Reprinted in Neugebauer, Otto (1983). Astronomy and History: Selected Essays. pp. 239–245.)
- Temple, Robert (1986). The Genius of China: 3000 years of science, discovery and invention. New York: Simon and Schuster. p. 55. ISBN 9780671620288.
- Turner, Anthony J. (1984). The Time Museum. Vol. I: Time Measuring Instruments, Part 3: Water-clocks, Sand-glasses, Fire-clocks. Rockford, IL: The Museum. ISBN 0-912947-01-2. OCLC 159866762.
Bibliography
Main article: Bibliography of water clocksExternal links
- The Clock of Flowing Time in Berlin Archived 2019-01-18 at the Wayback Machine
- NIST: A Walk Through Time – Early Clocks
- Bernard Gitton's Time-Flow Clocks Archived 2011-08-09 at the Wayback Machine
- Qanat is cultural, social and scientific heritage in Iran
- Egypt's Water Clock
- "Clepsydra" . Encyclopedia Americana. 1920.
- A Brief History of Clocks: From Thales to Ptolemy
- The Indianapolis Children's Museum Water Clock
- Nanaimo, BC Water Clock Archived 2007-08-11 at the Wayback Machine
- Animation: Ctesibius Water Clock
- Rees's Universal Dictionary article on Clepsydra, 1819
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- "Clepsydra" . New International Encyclopedia. 1905.
- The Mechanical Water Clock Of Ibn Al-Haytham
- computer servies on site on clocks
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