Solar System | Pythagoras | 500 BC | |
Golden year (nineteen-year astronomical cycle) | Meton | 432 BC | |
Helio-centric (sun centered) universe | AristArchus (then Copernicus) | Respectively 350BC then 1543 AD | |
Speaking Trumpet | Alexander the Great | 335 BC | |
Oldest written description of data transmission system (alphabet characters represented by code of up to five torch positions on two walls) | Polybius | 300BC | |
Length of tropical year (accuracy 12 seconds) | HippArchus | 145BC | |
Julian Calendar (prepared for Julius Ceasar) | Sosigenes | 45BC | |
Decimal notation | India | 900 | |
Magnetic compass (used 24 points, reckoned from south) | China | 12th century | |
Rockets in warfare | China | 1232 | |
Decimal notation introduced to Britain | - | 1253 | |
Difference between geographic and magnetic north pole | Columbus | 1492 | |
Helio-centric (sun centered) universe | Copernicus (after AristArchus) | 1543 | |
Mercator's map projection (Latinised form of name) | Kremer | 1560 | |
Calendar reform (not adopted by England until 1752) | Gregory | 1582 | |
Static electric forces described | Gilbert | 1600 | |
Telescope | Galileo | 1608 | |
First law - elliptical orbit | Kepler | 1609 | |
Second law - constant angular momentum (i.e., equal swept areas in orbital plane in equal time periods) | Kepler | 1609 | |
Third law - (orbital period)² ∞ (semi-major axis)³ | Kepler | 1618 | |
Calculating machine | Pascal | 1642 | |
Law of universal gravitation | Newton | 1666 | |
Semaphore with telescope | Hooke | 1684 | |
First law - inertia (Galileo's law of inertia). Second law - force, mass and acceleration. Third law - direct reaction | Newton | 1687 | |
Possibility of artificial earth satellite | Newton | 1687 | |
Insulated electrical lines | von Guericke | 1720 | |
Marine chronometer | Lloyd | 1735 | |
Gyroscope | Setson | 1744 | |
Capacitor (known as Leyden phial or jar) | Musschenbroek | 1746 | |
Electric conduction | Grey | 1720 | |
Electricity propagated by wire (3km) | Watson | 1747 | |
Gregorian calendar adopted by England | - | 1752 | |
Static electric telegraph (24 lines to 24 pitch-ball electrometres) | Lesage | 1774 | |
Single line static electric telegraph | Lomond | 1787 | |
Pulse position modulation (timed sparks at end of line) | Chappe | 1790 | |
Semaphore with mechanical arms | Chappe | 1794 | |
Six shutter optical telegraph | Murray | 1795 | |
Gravitational constant, G | Cavendish | 1797 | |
Electrolysis | Pearson | 1797 | |
Negative numbers | India | 1797 | |
Primary electric cell (silver zinc) | Volta | 1800 | |
Cloud formation classification | Howard | 1803 | |
Arc light | Davy | 1808 | |
Electro chemical telegraph (decomposed water - one line and electrode per character) | Soemmering | 1809 | |
Mechanical computing "engine" | Babbage | 1812 | |
Electro magnetism | Oersted | 1819 | |
Light as "waves" | Fresnel | 1820 | |
Magnetisation of soft iron | Arago and Faraday | 1820 | |
Multi turn coil as electro magnet "multiplier" | Schweigger | 1820 | |
Magnetised needle telegraph (one needle per character) | Ampre | 1820 | |
Single magnetic needle telegraph (coded characters -up to four serial digits per character) | Schiling | 1825 | |
Transformer (induction coil) | Faraday | 1831 | |
Commercial electric telegraph | Gauss and Weber | 1833 | |
Rectifier - asymmetric electric conduction | Munk | 1834 | |
Refrigeration | Perkins | 1834 | |
Five needle parallel coded telegraph | Wheatstone and Cooke | 1837 | |
Telegraph using signal relay at distant end to key fresh power source | Davy | 1838 | |
HF oscillations observed at a distance | Henry | 1840 | |
Frequency effects of relative motion (light from stars) | Doeppler | 1843 | |
Electromagnetic telegraph | Morse and Vail | 1844 | |
Incandescent lamp (carbon in vacuum) | Starr | 1845 | |
Telegraph printing roman characters instead of code | House | 1846 | |
Automatic telegraph transmitter | Bain and Wheatstone | 1846 | |
Gutta percha for submarine cables | Faraday | 1849 | |
Submarine telegraph cable (Connecticut River) | - | 1849 | |
Speaking tube | Wishaw | 1850 | |
Submarine telegraph single wire cable Dover to Calais (operated only one day) | Brett | 1850 | |
Submarine telegraph cable Dover to Calais (permanent - four, separated insulated wires) | - | 1851 | |
Fundamental system of electrical and magnetic measurements | Weber | 1851 | |
Duplex telegraphy | Gintl | 1853 | |
Microphone | Bourseul | 1854 | |
Transient response of a transmission line | Kelvin | 1855 | |
Electric lighthouse illumination (South Foreland) - Arc with clockwork spacing control | Foucault-Dubosq | 1858 | |
Telegraph polarised relay | Siemens | 1858 | |
Submarine telegraph, Ireland to USA 2630 km (initial cable only lasted for 700 messages) | Field | 1858 | |
Rubber insulation for cables | Hooper | 1859 | |
Submarine telegraph, transatlantic permanent (25 words per minute Morse code) | - | 1866 | |
Angstrom unit of length | Angstroem | 1868 | |
Gyro stabiliser | Watt - Boulton | 1868 | |
Navigational satellite proposal (a novel) | Hale | 1869 | |
British telegraph installations taken over by Post Office | - | 1870 | |
Multiplex telegraphy (f.d.m.) - morse code, mechanical resonance | Bell | 1870/1874 | |
Telephone | Bell | 1872 | |
500 b/s data transmission system | Edison | 1874 | |
Vacuum carbon filament dockyard lamps | Lodyguine | 1874 | |
First parallel connection of electric lamps (42 Arcs) | Farmer | 1875 | |
Multiplex telegraphy (t.d.m.) five unit code | Baudot | 1875 | |
Sidebands demonstrated in acoustics | Mayer | 1875 | |
Electro magnetic microphone - moving iron | Bell | 1876 | |
Carbon microphone | Edison | 1877 | |
Dynamic microphone - moving coil | Cuttris USA. Siemens Germany, then Wente | 18771931 | |
Magneto telephone exchange with drop indicators (New Haven Connecticut) | Jones | 1878 | |
Laser | Bell and Tainerthen Townes and Schawlow | 1878 1958 | |
First telephone exchange switchboard in Britain | - | 1879 | |
Piezo-electric effect | Curie | 1880 | |
Condenser microphone | Dolbearthen Wente | 18811917 | |
Thermionic emission | Edison | 1883 | |
Spark transmitter | Hertz | 1886 | |
Frequency division multiplex speech using mechanical resonance | Leblanc | 1886 | |
Parametric oscillation | Rayleigh | 1887 | |
Wireless telegraph (morse code) | Lodge | 1887 | |
Equalised line | Heaviside | 1887 | |
Radar | Hertz then Watson-Watt) | 18881937 | |
Ratchet-and-pawl telephone selector | Strowger | 1889 | |
Metallic valve filaments (platinum) | Fleming | 1890 | |
Submarine four core telephone cable Dover to Calais | - | 1891 | |
Standard primary cell - mercury-cadmium | Weston | 1892 | |
Electrical resonance and f.d.m. telephone system | Autin and Leblance | 1892 | |
Coherer detector | Branley | 1892 | |
Revised five unit telegraph alphabet (now called ITA No 2. | Murray | 1895 | |
Cathode ray tube | Crookes | 1895 | |
X-rays (discovered from c.r.t. experiments) | Roentgen | 1895 | |
Wireless telegraphy ship to ship | Jackson | 1895 | |
Commercial common-battery telephone exchange - Worcester Massachusetts | - | 1896 | |
Automatic telephone exchange Augusta New York | - | 1896 | |
Quarter wave antenna | MArconi | 1896 | |
Frequency tuning (called syntonic wireless) | Lodge | 1897 | |
Rectifier as a.m. detector | Pupin | 1898 | |
Coupling circuits | Braun | 1898 | |
Radio controlled model boat | Tesla | 1898 | |
Wireless telegraphy across English Channel | MArconi | 1899 | |
Thermionic emission consisting of electrons | Thomson | 1899 | |
Magnetic tape recording | Poulsen | 1899 | |
Telephone line repeaters | Lyons | 1900 | |
Radio telephony (2km with 10 kHz rotary spark gap) | Fessenden | 1900 | |
Amplitude modulated radio | Fessenden | 1901 | |
Wireless telegraphy Cornwall to Newfoundland | (Receiver at St John-Marconi transmitter at Poldhu-Fleming) | 1901 | |
British telephone systems taken over by Post Office | - | 1901/2 | |
Loaded transmission line (New York to Newark New Jersey) | Pupin | 1902 | |
Upper atmosphere reflection of radio | Heaviside | 1902 | |
Frequency modulation | Ehretthen Armstrong | 19021924 | |
Multi stage rocket theory defined | Tsiolkovsky | 1903 | |
Time division multiplex speech | Miner | 1903 | |
Arc transmitter with frequency shift keying (f.s.k.) | Poulsen | 1903 | |
Two electrode vacuum tube rectifier | Fleming | 1904 | |
Directional antennae | MArconi | 1905 | |
Quenched spark transmitter | Wien | 1906 | |
C.W. Oscillations | Poulsen | 1906 | |
320 km radio telephony | Fessenden | 1906 | |
High frequency alternators | Alexanderson | 1907 | |
Triode amplifier valve (called "audion") | de Forest | 1907 | |
Cathode ray oscillograph | Ryan | 1911 | |
Crystal microphone (led to ASDIC) | Langevin | 1914-1918 | |
Transatlantic radio telephony Arlington to Paris (transmitter with many paralleled triodes) | (USA) | 1915 | |
Sidebands in electrical communications | Carson | 1915 | |
Filters | Campbell | 1915 | |
Modulo-2 addition circuits (used for message encryption) | (Great Britain) | 1915 | |
Telephone New York - San Francisco (5200km over open wires) | - | 1915 | |
Maser | Einsteinthen Gordon, Zerger and Thomas | 19171954 | |
'Relay' automatic exchange telephone co-ordinate selector | Betulander | 1917 | |
Condenser microphone | Wente | 1917 | |
FM infinite sidebands and 'Carson's Rule' | Carson | 1922 | |
Ribbon microphone principle | Schottkythen Olsen | 19231931 | |
FM practical development | Armstrongafter Ehret | 19241902 | |
Radio facsimile cheque London to New York | Ranger | 1923 | |
Commercial radio facsimile transatlantic | - | 1926 | |
Tetrode (S625 valve) | Round | 1926 | |
Liquid propellant rocket | Goddard | 1926 | |
Mu-metal used for loading submarine cables (telegraph speed 2500 word per minute instead of 25) | - | 1926 | |
Rugby (UK) HF transmitter | - | 1927 | |
12 channel f.d.m. 400 word/min telegraph on single line pair (Western Electric) | (USA) | 1929 | |
Superhet receiver | Armstrong | 1930 | |
Improved dynamic (moving coil) microphone | Wente | 1931 | |
Improved ribbon microphone | Olsen | 1931 | |
Underground telephone cables in Britain | - | 1931 | |
Radio telescope | Jansky | 1931 | |
Microwave (20cm) telephone link Dover to Calais (56km) | - | 1931 | |
Cosmic noise discovered | Jansky | 1932 | |
FM 104km New York to Westhampton on 41 Mhz | Armstrong | 1933 | |
FM feedback demodulator | Chaffee | 1933 | |
Experimental crossbar telephone exchange Ericsson | (Sweden) | 1933 | |
Klystron | Varian | 1934 | |
Negative feedback amplifier (called inverse feedback | Black | 1934 | |
Coaxial telephone cable London - Birmingham (4 core, 280 circuit, 0.5 to 2.1 MHz, repeaters every 8 miles) | - | 1937 | |
Parabolic antenna | Reber | 1937 | |
Pulse code modulation | Reeves | 1937 | |
Radar | Watson-Watt | 1937 | |
Gas discharge lamp | - | 1938 | |
Crossbar telephone exchange Bell laboratories | (USA) | 1938 | |
I am born in July (future user of little sparks) | Harry and Dorothy (my parents) | 1938 | |
FSK data link for picture transmission (AntArctic) | Byrd | 1939 | |
Analogue vocoder | Dudley | 1939 | |
Bell complex-number computer model 1 | Stibitz | 1940 | |
Submerged repeater (Holyhead and Isle of Man) | - | 1943 | |
Havard Mk1 electronic computer (used 3304 electromagnetic relays) | Lake | 1944 | |
Multi stage combat rocket (Rheinbote) | (Germany) | 1944 | |
Delta modulation | Deloraine | 1945 | |
Synchronous global communication satellite system proposal | Clarke | 1945 | |
Travelling wave tube | Kompfner | 1945 | |
Atomic clock | Libby | 1946 | |
Moon bounce communications | (USA) | 1946 | |
Printed wiring component board | Sargrove | 1947 | |
Transistor | Shockley | 1948 | |
Experimental p.c.m. link of normal telephone quality | Meacham and Peterson | 1948 | |
Companding suggested for p.c.m. links | Reiling | 1948 | |
Bell tropospheric scatter communications ' beyond the horizon' | (USA) | 1952 | |
Backward-wave-oscillator or cArcinotron | (France) | 1952 | |
Cyclic binary code (e.g., for shaft encoders) | Gray | 1953 | |
Maser | Gordon Zerger and Townes | 1954 | |
Low altitude passive communication satellite proposal | Pierce | 1955 | |
Transatlantic telephone cable TAT1 Oban, Scotland to Clarenville Newfoundland 51 repeaters 144 Mhz ( 2 separate single core cables - one go and one return- providing 35 duplex 4khz telephone circuits plus 1 telegraph channel) | - | 1956 | |
Tunnel diode | Esaki | 1957 | |
Low noise microwave amplifier (synthetic ruby maser cooled to 2 Kelvins) | Bloembergen | 1957 | |
Artificial earth satellite SPUTNIK 1 (84kg, perigee 230km, apogee 950km) | (USSR) | 1957 | |
Laser (known then as 'optical maser' | Townes and Schawlow | 1958 | |
Store-and-forward communications satellite SCORE (3969kg, taped voice and teletype) | (USA) | 1958 | |
VHF ship to shore public radio telephone in Britain | - | 1958 | |
Transatlantic moon bounce communication, Joddrell Bank (with 33m diameter dish 200 Mhz at 1 kW) | (UK) | 1959 | |
Inflated passive communications satellite ECHO 1 (68kg, perigee 1400km, apogee 1800km) | (USA) | 1960 | |
Active, delayed-repeater communications satellite COURIER (227kg, perigee 970km, apogee 1240km, provided 16 duplex high speed teletype circuits) | (USA) | 1960 | |
Navigation satellite TRANSIT 1B | (USA) | 1960 | |
WOSTOCK manned satellite (4115kg, perigee 175km, apogee 302km) | Gagarin (USSR) | 1961 | |
Spin-stabilised communication satellite TELESTAR for experimental television | (USA) | 1962 | |
Duplex 12-circuit NASA satellite communication telephone experiment RELAY (with redundant transponders) | (USA) | 1962 | |
Synchronous communications satellite SYNCOM | (USA) | 1963 | |
Commercial geostationary communications satellite EARLY BIRD (INTELSAT 1) (240 telephone channels, or 1 TV channel via 2 single-access transponders) | (USA) | 1965 | |
INTELSAT II (240 telephone circuits or 1 TV channel via 1 multiple access transponder) | (USA) | 1969 | |
Military geostationary communications satellite SKYNET (launch USA) | (UK) | 1969 |