Billing was born in Salzwedel, in Saxony-Anhalt, Germany. After studying mathematics and physics in University of Göttingen he received his doctorate in 1938 in Munich at the age of 24. On 3 October 1943 he married Anneliese Oetker. Billing has three children: Heiner Erhard Billing, Dorit Gerda Gronefeld Billing and Arend Gerd Billing. He turned 100 in April 2014 and died on 4 January 2017 at the age of 102. Advanced LIGO detected the third gravitational wave event GW170104 on the same day.
Computer science
Billing worked at the Aerodynamic Research Institute in Göttingen, where he developed a magnetic drum memory. According to Billing's memoirs, published by Genscher, Düsseldorf, there was a meeting between Alan Turing and Konrad Zuse. It took place in Göttingen in 1947. The interrogation had the form of a colloquium. Participants were Womersley, Turing, Porter from England and a few German researchers like Zuse, Walther, and Billing.. After a brief stay at the University of Sydney, Billing returned to join the Max Planck Institute for Physics in 1951. From 1952 through 1961 the group under Billing's direction constructed a series of four digital computers: the G1, G2, G1a, and G3. He is the designer of the first German sequence-controlled electronic digital computer as well as of the first German stored-program electronic digital computer.
Gravitational wave detector
After transistors had been firmly established, when microelectronics arrived, after scientific computers were slowly overshadowed by commercial applications and computers were mass-produced in factories, Heinz Billing left the computer field in which he had been a pioneer for nearly 30 years. In 1972, Billing returned to his original field of physics, at the Max Planck Institute's new location at Garching near Munich. Beginning in 1972, Heinz Billing became involved in gravitational physics, when he tried to verify the detection claims made by American physicist Joseph Weber. Weber's results were considered to be proven wrong by these experiments. In 1975, Billing acted on a proposal by Rainer Weiss from the Massachusetts Institute of technology to use laser interferometry to detect gravitational waves. He and colleagues built a 3m prototype Michelson interferometer using optical delay lines. From 1980 onward Billing commissioned the development and construction in MPA in Garching of a laser interferometer with an arm length of 30m. Without the knowledge gained from this prototype, the LIGO project would not have been started when it did.
Heinz Billing, Albrecht Rüdiger: Das Parametron verspricht neue Möglichkeiten im Rechenmaschinenbau. In: eR - Elektronische Rechenanlagen. Band 1, Heft 3, 1959.
Heinz Billing: Lernende Automaten. Oldenbourg Verlag, München 1961.
Heinz Billing: Die im MPI für Physik und Astrophysik entwickelte Rechenanlage G3. In: eR - Elektronische Rechenanlagen. Band 5, Heft 2, 1961.
Heinz Billing: Magnetische Stufenschichten als Speicherelemente. In: eR - Elektronische Rechenanlagen. Band 5, Heft 6, 1963.
Heinz Billing: Schnelle Rechenmaschinenspeicher und ihre Geschwindigkeits- und Kapazitätsgrenzen. In: eR - Elektronische Rechenanlagen. Band 5, Heft 2, 1963.
Heinz Billing, Albrecht Rüdiger, Roland Schilling: BRUSH - Ein Spezialrechner zur Spurerkennung und Spurverfolgung in Blasenkammerbildern. In: eR - Elektronische Rechenanlagen. Band 11, Heft 3, 1969.
Heinz Billing: Zur Entwicklungsgeschichte der digitalen Speicher. In: eR - Elektronische Rechenanlagen. Band 19, Heft 5, 1977.
Heinz Billing: A wide-band laser interferometer for the detection of gravitational radiation. progress report, Max-Planck-Institut für Physik und Astrophysik, München 1979.
Heinz Billing: Die Göttinger Rechenmaschinen G1, G2, G3. In: Entwicklungstendenzen wissenschaftlicher Rechenzentren, Kolloquium, Göttingen. Springer, Berlin 1980,.
Heinz Billing: The Munich gravitational wave detector using laser interferometry. Max-Planck-Institut für Physik und Astrophysik, München 1982.
Heinz Billing: Die Göttinger Rechenmaschinen G1, G2 und G3. In: MPG-Spiegel. 4, 1982.