Record Setting Silicon Resonator Reaches 4.51 GHz

bibekpaudel brings news that researchers from Cornell University have developed a very small silicon microresonator that vibrates at the highest frequency ever recorded for such a device: 4.51 GHz. Typical quartz-crystal oscillators, commonly used in electronics as clock signals, are about a millimeter wide and operate in the KHz - MHz range. The newly developed microresonator measures 8.5 micrometers long and 40 micrometers wide, making it ideal for use in smaller circuits and microprocessing. Quoting: "One of the advantages of silicon microresonators is that they can be integrated directly into microchips using conventional manufacturing techniques, making them cheaper to produce and easier to fabricate small. Also, multiple resonators of different frequencies could be put on the same chip, says Ville Kaajakari, an assistant professor of electrical engineering at Louisiana Tech University. In a cell phone, for example, high-frequency resonators could filter out interference from other sources of radio signals."

Re:this will benefit lower freq apps too

[AdamHaun]

You don't do it with a CPU. You do it in hardware with a digital counter, like this:

http://www.play-hookey.com/digital/ripple_counter.html

Dividing by two is easy -- just take the output of one of the flip-flops. Dividing by other numbers can be done by connecting the flip-flop outputs and/or their complements to an AND gate. This requires some extra circuitry and wiring, but in an integrated circuit the overhead will be insignificant. Even in a discrete circuit, if you make the reference 2^32Hz (~4.2GHz), you're only looking at maybe two counter ICs to divide down to 1Hz, although no counter IC I know of can handle a 4GHz signal.

The real issue with using this would be whether your manufacturing process can make transistors fast enough for it. The quote in the summary suggests this will be popular in an analog role for high-frequency applications like wireless. Maybe we'll see discrete timing references too.