Sidney Darlington


In a field where components and systems are often known by sterile strings of characters that manufacturers assign or by cutesy names that are clearly products of the marketing department and their focus groups, having your name attached to an innovation is rare. Rarer still is the case where the mere mention of an otherwise obscure inventor’s name brings up a complete schematic in the listener’s mind.

Given how rarely such an honor is bestowed, we’d be forgiven to think that Sidney Darlington’s only contribution to electronics is the paired transistor he invented in the 1950s that bears his name to this day. His long career yielded so much more, from network synthesis theory to rocket guidance systems that would eventually take us to the Moon. The irony is that the Darlington pair that made his name known to generations of engineers and hobbyists was almost an afterthought, developed after a weekend of tinkering.

A Passion for Networks

With her background as a teacher in a one-room schoolhouse on the edge of the American prairie, Sidney Darlington’s mother was determined that her children would have the best educations possible. His father, a mechanical engineer, was likely an influence on Sidney and his brother Philip, both of whom embarked on scientific careers. Philip chose biology while Sidney chose physics, which he studied at Harvard. After graduating in 1928, he earned a second B.S. in electrical engineering the following year from MIT.


Sidney Darlington. Source: IEEE

Having been instilled with a passion for circuit analysis by his professors, in 1929 Sidney went to work at Bell Laboratories, then the center of the electrical engineering universe. He quickly found his way to the lab’s Mathematics Research Center, where his interest in circuit analysis would prove key to designing the complex filter networks needed to support the nascent technology of multiplexing, which can be used to stuff multiple telephone signals through one cable.

At the time, filter design was largely a trial and error affair where different filtering stages were connected together to achieve the desired result. This was inefficient from a design standpoint, and the filters often ended up not behaving quite as intended due to loading introduced by the various stages. Darlington’s method of filter design, known as network synthesis, took these impedances into account from the start, resulting in better filters and better networks.

Having already established a name for himself as well as a legacy, and with World War II in the offing, Darlington turned his work toward military needs. His theoretical bent and gift for mathematics made the problems involved with putting munitions on target an interesting one, and Darlington ended up making significant contributions to both bombsight designs and fire control systems for artillery. Near the end of the war he took a leave of absence from Bell to join the 14th Antiaircraft Command in the South Pacific as a civilian advisor.

More Than The Sum

With the conclusion of the war and the ensuing rush to switch basic research from military goals to commercial targets, Bell Labs swung into high gear, and Darlington played no small part in the activity. The invention of the transistor in 1947 by colleagues William Shockley, John Bardeen, and Walter Brattain piqued Darlington’s passion for circuit theory. By the early 1950s, the transistor had been transformed from physics lab oddity to an engineered commercial product, and Darlington grabbed a few to play with on his way home one day. The silicon transistors the Bell Labs had were relatively low-gain units, and Darlington was keen to find ways to increase the gain.


Darlington Pair. Note the suggestion of monolithic construction. Darlington lamented that if the patent lawyer hadn’t insisted on showing only two transistors, every integrated circuit would have had to pay royalties to Bell Labs. Source: U.S. Patent 2,663,806

He breadboarded a few circuits before hitting on a paired topology – common collectors with the emitter of the first transistor tied to the base of the second. He reasoned that the pair would behave like a single transistor but with more current gain. He thought the gain would double, turning a pair of transistors with a gain of five into a single device with a gain of ten. He was surprised to learn that the gains multiplied, giving a gain of 25.

Knowing that he had a major innovation on his hands, he worked up the device back in the lab, characterizing the properties of compound transistors. He tried different circuits, some with common emitters rather than common collectors, and some with three transistors ganged together. But the common collector pair of NPN transistors was the most promising. Apart from the huge gain increase, the common collector arrangement naturally favored a simple fabrication method, where the two transistors could be built on a single slab of N-type silicon. Such an arrangement is described in Darlington’s 1953 patent application, and is one of the first suggestions that complex circuits could be built up monolithically on a single substrate.


Darlington pair in a decapped TO-3 case. The die is bonded to the emitter (top) and base (bottom) leads, while the case serves as the common collector. Source: Wikipedia

Darlington would enjoy another two decades at Bell Labs, retiring in 1971. In that time he would also invent a guidance system for rockets that would find its way into the Titan I and Thor-Delta boosters, helping to usher in the Space Age. He also turned his signal processing prowess to radar, inventing a pulse compression or “chirp” radar system that became critical in the development of anti-ballistic-missile radar systems.

For as rich and inventive a life as Sidney Darlington lived, it seems fitting that we remember him today mainly for something he just whipped up at the bench one weekend. Much like any of us, he just wanted to press the limits of a new technology, and he was one of the lucky ones that found something so simple and so useful that his name lives on.



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