The resolver is its more refined sibling, using two output windings (sine and cosine) rather than three. This makes it mathematically purer and, therefore, the darling of aerospace and defense applications.
In a conference room in East Aurora, New York (Moog’s global headquarters), there is probably a worn copy on a shelf. And somewhere right now, an engineer is opening a PDF of that same handbook. They are trying to figure out why their resolver’s sine-cosine mismatch is 0.5% at 25°C but 1.2% at 85°C. They will find the answer in a footnote on page 4-17. And they will be grateful. Synchro And Resolver Engineering Handbook Moog Inc
The Synchro and Resolver Engineering Handbook is not just a manual. It is a monument to the era when feedback was analog, when noise was a physical force to be grappled with, and when a company like Moog could build a lasting reputation not just on the hardware it sold, but on the knowledge it freely shared. The resolver is its more refined sibling, using
But a servovalve is useless without a command. And that command, in early fly-by-wire systems, missile guidance platforms, and naval gun directors, came from synchros and resolvers. And somewhere right now, an engineer is opening
For over half a century, this handbook has been more than a product catalog. It is a Rosetta Stone for translating the physical world of rotating machinery into the precise, unforgiving language of electronic feedback. Before optical encoders became cheap and ubiquitous, before Hall-effect sensors saturated the market, the synchro and the resolver were the undisputed kings of angular measurement. And Moog Inc.—a company more famous for its hydraulics on fighter jets and amusement park rides—wrote the definitive text on how to wield them.
And then there were the application diagrams. Beautiful, messy schematics showing how to use a single resolver to measure both azimuth and elevation via a mechanical differential. Circuits for “electronic gearing” that predated digital motion controllers by twenty years. A diagram for a “synchro-to-digital converter” built from discrete comparators, counters, and a precision D/A converter—a project that would take a month to debug but teach you more about sampling theory than any textbook. By the late 1990s, the writing was on the wall. Optical encoders with 16-bit resolution were dropping in price. Resolver-to-digital (R/D) converters existed as single-chip solutions from Analog Devices or DDC. The need to understand the analog soul of a resolver seemed to be fading.