It took the combined experiences of several types of CMOS silicon designers
to come up with the smallest high-performance low-cost microelectromechanical-system
(MEMS) oscillator on the market.
This feat was accomplished by SiTime, a startup fabless integrated circuit company based in Sunnyvale, Calif. The firm developed a vacuum-sealed MEMS First process that allowed the novel on-chip integration of the MEMS sensing element and temperature-compensation circuitry within industry-standard packages.
The process created a tiny, vibrating mechanical resonator (see
the figure). MEMS First promises to revolutionize timing for a wide range
of products. Its initial markets will include cell phones, digital cameras,
digital TVs, DVD players, and electronic games. Until now, the venerable quartz
crystal oscillator dominated these consumer applications.
Clocks lie at the heart of every electronic product. Therefore, being able
to produce low-cost integrated MEMS transducers on a standard CMOS process will
have a wide effect on the industry. SiTime achieved this low cost by using batch
fabrication on an 8-in. (200-mm) CMOS wafer. This wafer format can hold some
50,000 MEMS First resonators, compared with 200 to 300 on an AT-cut (high-frequency)
quartz crystal and about 500 on a tuning-fork (32.768-Hz) quartz crystal.
SiTime's initial product families, the SiT11xx fixed-frequency and SiT8002
programmable oscillators, employ 0.18- m design rules. They're based on the
proprietary MEMS First process developed at Germany-based Robert Bosch GmBH.
Other MEMS sensor technologies pioneered by Bosch include the deep-trench process
for surface micromachined accelerometers and gyros, as well as the use of bulk
micromachining for air-flow mass sensors and integrated pressure sensors. The
MEMS First process achieves a high-Q in-situ vacuum sealing under high-temperature
processing.
The SiT8002 is the industry's smallest programmable oscillator, according to the company, with performance that exceeds comparable quartz products. The device is housed in industry-standard plastic packages. It supports cost-effective solutions that compete with and replace other crystal oscillator types. Unlike quartz crystal technology, silicon-based resonators can be integrated easily. As a result, MEMS First oscillators can incorporate many additional time-reference functions on-chip.
Silicon MEMS oscillators have been around for many years, using mechanical vibrating resonators to perform timing. MEMS pioneer and entrepreneur Kurt Petersen, SiTime's chief executive officer and founder, first proposed the use of silicon as a mechanical material back in the 1970s. This later led to many MEMS device developments, including resonating-beam oscillators.1
Yet issues like silicon's 30-ppm/ C temperature coefficient, the demand for
complex temperature-compensation circuitry, and the need to use metal or ceramic
packages hindered the commercial viability of silicon oscillators. Quartz oscillators
also require more expensive metal or ceramic packaging, but they have a natural
high stability over temperature when processed properly (see
the table).
ROCK-SOLID STABILITY
The MEMS First process, which provides long-term stability,
solves the temperature-stability problem in silicon resonators. During its first
year of operation (usually the worst year in terms of aging and stability),
the MEMS First silicon oscillator achieved long-term stability of 0.05 ppm,
limited only by the measurement capability available. That compares with 3 ppm
for quartz and 30 to 100 ppm for other silicon MEMS oscillators.
A team led by Bernhard Boser, SiTime's chief scientist and a professor at the
University of California at Berkeley, developed the chip's crucial temperature-compensation
circuitry. This circuitry consists of the MEMS resonator, an oscillator, a phase-locked
loop, digital temperature compensation, an analog-to-digital converter (ADC),
and a temperature sensor.
MEMS First resonators have been tested-over 1000 full-scale, industrial temperature-range cycles, from -50°C to 80°C for 6000 hours with 0 ppm of frequency change related to thermal hysteresis. MEMS First also features excellent immunity to shock and vibration compared to quartz crystals.
The key breakthrough in the development of the MEMS First oscillator was its high-temperature sealing system. Above 1100 C, epitaxial silicon is used to encapsulate the device. This innovation came from the minds of Markus Lutz, SiTime's chief operating officer, and Aaron Partridge, SiTime's chief technology officer, while working at Robert Bosch.
"The packaging, encapsulation, and vacuum processing we use make the MEMS First device far more stable than other types of oscillators," says John McDonald, SiTime's vice president of marketing.