The need to quantum time arose with the amelioration of agriculture. Farmers used timekeeping to settle the best planting periods and primitive lunar calendars were made.
The Egyptians were the first habitancy to construct extensively a means of telling time with calendars and clocks. By around 2800 Bc they had established a 365-day calendar, based on their observations of the rising and setting of challenging stars such as Sirius and of the periodic inundations of the Nile, upon which their agriculture relied. By 2100 Bc the Egyptians had devised a way to divide the day into 24 hours. around the same time, they made the first sundials, or shadow clocks, to quantum time while the day. A sundial indicates the time of day by the position of the shadow of some object on which the sun's rays fall.
Piezoelectric
By 1500 Bc Egyptians had invented another, more accurate, way of telling time-the water clock or a clepsydra, which uses the steady dripping of water from a vessel to drive a mechanical expedient that indicates the hour.
Babylonian astronomers' fine tuned the clepsydra taking into catalogue the equation of time caused by the varying length between the Earth and the sun as it moves in an elliptical orbit. Due to this effect, noon could be as much as a half hour before or after the time when the sun is highest in the sky.
Around 270 Bc the Alexandrian engineer Ctesibios designed water clocks that rang bells, moved puppets, and caused mechanical birds to sing. The water clock remained in use until the amelioration of mechanical clocks nearly 3,000 years later.
Measurement of short time intervals, however, was possible with the hourglass. The hunt for definite clocks began with the burgeoning late medieval manufactures and the first fruits of the scientific revolution. This need lead to the mechanical clocks which measured time with simple weighted pendulums. But these were not portable.
The first watches
The invention of springs and escapement mechanism ushered in the era of movable watches. The escapement is a mechanism that controls and limits the unwinding of the watch, converting what would otherwise be a simple unwinding, into a controlled and periodic power release. The escapement does this by interlocking with a gear in a simple manner that switches between a "driven" and a "free" state, with abrupt locking at each end of the cycle. The escapement also for the same hypothesize produces the ticking noise characteristic of mechanical watches.
Another mechanical method is the equilibrium wheel mechanism. The equilibrium wheel together with the equilibrium spring (also known as Hairspring) - these form a simple harmonic oscillator, which controls the appeal of the gear system of the watch in a manner analogous to the pendulum of a pendulum clock. This is possible because the occasion of inertia of the equilibrium wheel is fixed, and the wheel as a whole provides a quarterly appeal of known period. These watches produce a ticking sound.
Purely mechanical watches are still popular. The high level of craftsmanship of purely mechanical watches accounts for much of their attraction. Compared to electronic movements, mechanical watches are inaccurate, often with errors of seconds per day. They are often sensitive to position and temperature, they are costly to produce, they want quarterly maintenance and adjustment, and they are more prone to failure.
Further accuracy was achieved in the sixties by Tuning fork watches, which use a tuning fork at a definite frequency (most often 360 hertz) to drive a mechanical watch. Since the fork is used in place of a typical equilibrium wheel, these watches simply hum instead of tick. Tuning fork movements are electromechanical. The task of converting electronically pulsed fork vibration into rotary movement is done via two tiny jeweled fingers, called pawls, one of which is connected to one of the tuning fork's tines. As the fork vibrates, the pawls no ifs ands or buts ratchet a tiny index wheel. This index wheel has over 300 barely illustrated teeth and spins more than 38 million times per year. The tiny galvanic coils that drive the tuning fork have 8000 turns of insulated copper wire with a diameter of 0.015 mm and a length of 90 meters. This spectacular, feat of engineering was prototyped in the 1950s and the early 60's.
Advent of the electronic quartz watch in 1969
In 1948, Max Hetzel used an electronic device, a transistor to create the first electronic watch. This amelioration became obsolete with the use of a quartz crystal which brought in the quartz watches, which use the piezoelectric ensue in a tiny quartz crystal to supply a stable time base for a mostly electronic movement: the crystal forms a quartz oscillator which resonates at a specific and highly stable frequency, and which can be used to accurately pace a timekeeping mechanism. These primarily electronic movements are geared to drive mechanical hands on the face of the watch. Quartz movements are ten times good than a mechanical movement.
Further developments introduced the following types of watches:
Manual watches
In manual watches the spring must be rewound by the user periodically by turning the watch crown.
Self-winding or automatic watches
A self-winding or automatic mechanism is one that rewinds the mainspring of a mechanical movement by the natural motions of the wearer's body.
Kinetic power or automatic quartz
Some electronic watches are also powered by the movement of the wearer of the watch. Kinetic powered quartz watches make use of the appeal of the wearer's arm turning a rotating weight, which turns a generator to supply power to payment a rechargeable battery that runs the watch. The view is similar to that of self-winding spring movements, except that the electrical power is generated instead of mechanical spring tension.
Battery powered watches in 1957
Electronic watches want electricity as a power source. Some mechanical movements and hybrid electronic-mechanical movements also want electricity. Normally the electricity is in case,granted by a replaceable battery. Watch batteries (strictly speaking cells) are specially designed for their purpose. They are very small and supply tiny amounts of power continuously for very long periods (several years or more). Environment unfriendly mercury batteries gave way to Silver-oxide and lithium batteries. Cheap batteries may be alkaline, of the same size as silver-oxide but providing shorter life. Rechargeable batteries are used in some solar powered watches.
Light-powered watches
Some electronic watches are powered by light. A photovoltaic cell on the face of the watch converts light to electricity, which in turn is used to payment a rechargeable battery. The movement of the watch draws its power from the rechargeable battery. As long as the watch is Normally exposed to fairly strong light (such as sunlight), it never needs battery replacement, and some models need only a few minutes of sunlight to supply weeks of energy.
Some of the early solar watches of the 1970s had innovative and unique designs to adapt the array of solar cells needed to power them (Nepro, Sicura and some models by Cristalonic, Alba, Seiko and Citizen). As the decades progressed and the efficiency of the solar cells increased while the power requirements of the movement and display decreased, solar watches began to be designed to look like other conventional watches.
Radio-controlled movements
Some electronic quartz watches are able to synchronize themselves with an external time source. These sources contain radio time signals directly driven by atomic clocks, time signals from Gps pilotage satellites, the German Dcf77 signal in Europe, Wwvb in the Us, and others. These watches are free-running most of the time, but periodically align themselves with the chosen external time source automatically, typically once a day.
Because these watches are regulated by an external time source of extraordinarily high accuracy, they are never off by more than a small fraction of a second a day (depending on the potential of their quartz movements), as long as they can receive the external time signals that they expect. Additionally, their long-term accuracy is comparable to that of the external time signals they receive, which in most cases (such as Gps signals and extra radio transmissions of time based on atomic clocks) is good than one second in three million years. For all practical purposes, then, radio-controlled wristwatches keep near perfect time.
Movements of this type synchronize not only the time of day but also the date, the leap-year status of the current year, and the current state of daylight salvage time (on or off). They gain all of this facts from the external signals that they receive. Because of this continual automatic updating, they never want manual setting or resetting.
A disadvantage of radio-controlled movements is that they cannot synchronize if radio reception conditions are poor. Even in this case, however, they will simply run autonomously with the same accuracy as a general quartz watch until they are next able to synchronize.
Watch display
In the seventies two types of displays were developed.
Analog display
A numbered dial upon which are mounted at least a rotating hour hand and a longer, rotating diminutive hand. Many watches also join a third hand that shows the current second of the current minute. Watches powered by quartz have second hands that snap every second to the next marker. Watches powered by a mechanical movement have a "sweep second hand", the name deriving from its uninterrupted plane (sweeping) movement across the markers, the hand merely moves in smaller steps, typically 1/6 of a second, corresponding to the beat of the equilibrium wheel. All of the hands are Normally mechanical, physically rotating on the dial, although a few watches have been produced with "hands" that are simulated by a liquid-crystal display.
Digital display
A digital display simply shows the time as a number, e.g., 12:40 Am instead of a short hand pointing towards the number 12 and a long hand pointing towards the number 8 on a dial.
The Led displays were superseded by (Lcds), which used less battery power and were much more favorable in use, with the display always illustrated and no need to push a button before looking the time.
From the 1980s onward, technology in digital watches vastly improved. New features were added every year.
1982 Seiko produced a watch with a small built in Tv screen
1983 Casio produced a digital watch with a thermometer and another watch that could translate 1,500 Japanese words into English
1985 Casio produced the Cfx-400 scientific calculator watch.
1987 Casio produced a watch that could dial your telephone number and habitancy one that would react to your voice.
1995 Timex publish a watch which allowed the wearer to download and store data from a computer to their wrist.
History of the Watch