C.C.W. Ruppel scite author profile

Today, acoustic filters are the filter technology to meet the requirements with respect to performance dictated by the cellular phone standards and their form factor. Around two billion cellular phones are sold every year, and smart phones are of a very high percentage of approximately two-thirds. Smart phones require a very high number of filter functions ranging from the low double-digit range up to almost triple digit numbers in the near future. In the frequency range up to 1 GHz, surface acoustic wave (SAW) filters are almost exclusively employed, while in the higher frequency range, bulk acoustic wave (BAW) and SAW filters are competing for their shares. Prerequisites for the success of acoustic filters were the availability of high-quality substrates, advanced and highly reproducible fabrication technologies, optimum filter techniques, precise simulation software, and advanced design tools that allow the fast and efficient design according to customer specifications. This paper will try to focus on innovations leading to high volume applications of intermediate frequency (IF) and radio frequency (RF) acoustic filters, e.g., TV IF filters, IF filters for cellular phones, and SAW/BAW RF filters for the RF front-end of cellular phones.

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Spread spectrum communications using chirp signals

Springer¹,

Gugler²,

Huemer³

et al.

126

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Ahtmct-We report on the use of broadband chirp s i p nals for spread spectrum systems in indoor applications. The presented system concepts make use of chirp transmission and pulse compression. Different modulation schemes for chirp signals resulting in different system performance and complexity are compared in terms of bit error rate for the AWGN channel and for frequency selective indoor radio channels. We present simulations and measurement results from demonstrator systems which use surface acoustic waveSAW) devices for the generation and matched Altering of the chirp signals. RF and IF frequency and transmission bandwidth of the presented systems are 2.4 GHz, 348.8 MHa, and 80 MHz, respectively. Due to the processing gain of 16 dB -made possible by the use of SAW devices -and the large transmission bandwidth the system is insensitive against frequency selective fading, CW interference and noise.

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Microwave acoustic materials, devices, and applications

Weigel¹,

Morgan²,

Owens

et al. 2002

IEEE Trans. Microwave Theory Techn.

161

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SAW devices as wireless passive sensors

Reindl

Scholl

Ostertag

et al.

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C.C.W. Ruppel

Improved material constants for LiNbO/sub 3/ and LiTaO/sub 3/

Acoustic Wave Filter Technology–A Review

Spread spectrum communications using chirp signals

Microwave acoustic materials, devices, and applications

SAW devices as wireless passive sensors

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