TY - GEN
T1 - Modellierung eines neuartigen Kamm-Mikrofons mit hohem Signal-Rausch-Verhältnis
AU - Manz, Johannes
AU - Schrag, Gabriele
AU - Dehé, Alfons
AU - Krumbein, Ulrich
AU - Wachutka, Gerhard
N1 - Publisher Copyright:
© 2017 MEMS.All right reserved.
PY - 2017
Y1 - 2017
N2 - Strong competition within the consumer market urges the companies to constantly improve the quality of their devices. For silicon microphones excellent sound quality is the key feature in this respect, which means that improving the signal-to-noise ratio (SNR) and thus the sound quality, is a major task to fulfill the growing demands of the market. MEMS microphones with conventional capacitive readout suffer from noise caused by viscous damping losses arising from perforations in the backplate [1]. Therefore, we conceived a novel microphone design based on capacitive read-out via comb structures, which is supposed to show a reduction in fluidic damping compared to the conventional device concept. In order to evaluate the potential of the proposed design, we developed a fully energy-coupled, modular system-level model. All submodels are physically based and scale with all relevant design parameters. We carried out noise analyses and due to the modular and physics-based character of the model, were able to discriminate the noise contributions of different parts of the microphone. This enables us to identify design variants of this concept which exhibit a SNR of up to 73dB(A). This is superior to conventional and, at least, comparable to high-performance variants of the current state-of-the art MEMS microphones [2].
AB - Strong competition within the consumer market urges the companies to constantly improve the quality of their devices. For silicon microphones excellent sound quality is the key feature in this respect, which means that improving the signal-to-noise ratio (SNR) and thus the sound quality, is a major task to fulfill the growing demands of the market. MEMS microphones with conventional capacitive readout suffer from noise caused by viscous damping losses arising from perforations in the backplate [1]. Therefore, we conceived a novel microphone design based on capacitive read-out via comb structures, which is supposed to show a reduction in fluidic damping compared to the conventional device concept. In order to evaluate the potential of the proposed design, we developed a fully energy-coupled, modular system-level model. All submodels are physically based and scale with all relevant design parameters. We carried out noise analyses and due to the modular and physics-based character of the model, were able to discriminate the noise contributions of different parts of the microphone. This enables us to identify design variants of this concept which exhibit a SNR of up to 73dB(A). This is superior to conventional and, at least, comparable to high-performance variants of the current state-of-the art MEMS microphones [2].
UR - http://www.scopus.com/inward/record.url?scp=85096805075&partnerID=8YFLogxK
M3 - Konferenzbeitrag
AN - SCOPUS:85096805075
T3 - MikroSystemTechnik Kongress 2017 "MEMS, Mikroelektronik, Systeme", Proceedings
SP - 30
EP - 33
BT - MikroSystemTechnik Kongress 2017 "MEMS, Mikroelektronik, Systeme", Proceedings
PB - VDE VERLAG GMBH
T2 - MikroSystemTechnik Kongress 2017: MEMS, Mikroelektronik, Systeme - MikroSystemTechnik Conference 2017: MEMS, Microelectronics, Systems
Y2 - 23 October 2017 through 25 October 2017
ER -