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Low Power Half-Run RC5 Cipher Circuit for Portable Biomedical Device and A Frequency-Shift Readout Circuit for FPW-Based BiosensorsLin, Yain-Reu 08 August 2011 (has links)
This thesis consists of two topics. We proposed a low power half-run RC5 cipher for portable biomedical devices in the first part of this thesis. The second topic is to realize a frequency-shift readout system for FPW-based biosensors.
In the first topic, a half-round low-power RC5 encryption structure is proposed. To reduce hardware cost as well as power consumption, the proposed RC5 cipher adopts a resource-sharing approach, where only one adder/subtractor, one bi-directional barrel shifter, and one XOR with 32-bit bus width are used to carry out the entire design. Two data paths are switched through the combination of four multiplexers in the encryption/decryption procedure. For the sake of power reduction, the clock in the key expansion can be turned off when all subkeys are generated.
In the second topic, an IgE antigen concentration measurement system using a frequency-shift readout method for a two-port FPW (flexural plate-wave) allergy biosensor is presented. The proposed frequency-shift readout method adopts a peak detecting scheme to detect the resonant frequency. A linear frequency generator, a pair of peak detectors, two registers, and an subtractor are only needed in our system. According to the characteristics of the FPW allergy biosensor, the frequency sweep range is limited in a range of 2 MHz to 4 MHz. The precision of the measured frequency is proved to the 4.2 kHz/mV, which is for better than that of existing designs.
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Development of FPW Device with Groove Reflection Structure DesignJames, Chang 06 September 2011 (has links)
Utilizing bulk micromachining technology, this thesis aimed to develop a flexural plate-wave(FPW) device with novel groove reflection microstructure for high-sensitivity and low insertion-loss biomedical microsystem applications. The influences of the amount and depth of the groove and the distance between the groove and the boundary of ZnO piezoelectric thin-film (DGB) on the reduction of insertion-loss and the enhancement of quality factor (Q) and electromechanical coupling coefficient (K2) were investigated. Three critical technology modules established in this thesis are including the development of (1) a sputtering deposition process of high C-axis (002) orientation ZnO piezoelectric thin-film, (2) an electrochemical etch-stop technique of silicon anisotropic etching and (3) an integration process of FPW device.
Firstly, under the optimized conditions of the sputtering deposition process (300¢J substrate temperature, 200 W radio-frequency (RF) power and 30/70 Ar/O2 gas flow ratio), a high C-axis (002) orientated ZnO piezoelectric thin-film with a high X-ray diffraction (XRD) intensity (50,799 a.u.) and narrow full width at half maximum (FWHM = 0.383¢X) can be demonstrated. The peak of XRD intensity of the standard ZnO film occurs at diffraction angle 2£c = 34.422¢X, which matches well with our results (2£c = 34.357¢X). Secondary, an electrochemical etch-stop system with three electrode configuration has been established in this research and the etching accuracy can be controlled to less than 1%. Thirdly, this thesis has successfully integrated the main fabrication processes for developing the FPW device which are including six thin-film deposition processes and six photolithography processes. The implemented FPW device with RIE etched groove reflection microstructure presents a low insertion-loss of -12.646 dB, center frequency of 114.7 MHz, Q factor of 12.76 and K2 value of 0.1876%.
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A dB-Linear Programmable Variable Gain Amplifier and A Voltage Peak Detector with Digital Calibration for FPW-based Allergy Antibody Sensing SystemHsiao, Wei-Chih 10 July 2012 (has links)
This thesis proposes a dB-linear programmable variable gain amplifier (VGA) and a voltage peak detector with digital calibration for FPW-based antibody sensing system.
In the first topic, a dB-linear programmable variable gain amplifier is proposed. By using two source followers as the input terminals, input signals with very low DC offset could be received. The linear local-feedback transconductors are employed to be trans-condurctor-stage and load-stage. Besides, a reconfiguration method is used to reduce the layout area and improve the linearity of the gain to attain gain error less than 0.86 dB measured on silicon.
In the second topic, a voltage peak detector with digital calibration is proposed. The voltage peak of the input sine-wave signal is sampled and held by using an integra-tor, a digital-to-analog converter, and a voltage comparator to generate a square-wave signal. Besides, the voltage error caused by the propagation delay could be calibrated by the proposed digital calibration method. The frequency of input signal is up to 20 MHz and the voltage error is justified to be less than 0.81 % by simulations.
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Development of Flexural Plate-wave Device with Silicon Trench Reflective Grating StructureHsu, Li-Han 30 July 2012 (has links)
Abstract
Compared with the other micro acoustic wave devices, the flexural plate-wave (FPW) device is more suitable for being used in liquid-sensing applications due to its higher mass sensitivity, lower phase velocity and lower operation frequency. However, conventional FPW devices usually present a high insertion loss and low fabrication yield.
To reduce the insertion loss and enhance the fabrication yield of FPW device, a 1.5 £gm-thick silicon-trench reflective grating structure (RGS), a high electromechanical coupling coefficient ZnO thin-film and a 5 £gm-thick silicon oxide membrane substrate are adopted in this research. The influences of the amount of silicon trench and the distance between inter-digital transducer (IDT) and RGS on the insertion loss and quality factor of FPW device are investigated. The main fabrication technology adopted in the study is bulk micromachining technology and the main fabrication steps include six thin-film deposition and five photolithography processes.
Under the optimized conditions of the sputtering deposition processes (200¢J substrate temperature, 200 W radio-frequency power and 75% gas flow ratio), a high C-axis (002) orientation ZnO piezoelectric thin-film with 31.33% electromechanical coupling coefficient can be demonstrated. The peak of XRD intensity of the standard ZnO film occurs at diffraction angle 2£c = 34.422¢X, which matches well with our results (2£c = 34.282¢X). By controlling the thickness of ZnO/Au/Cr/SiO2/Si3N4 sensing membrane less than 6.5 £gm-thick, the fabrication yield of FPW device can be improved and a low operation frequency (6.286 MHz) and high mass sensitivity (-113.63 cm2 / g) can be achieved. In addition, as the implemented FPW device with four silicon trenches RGS and 37.5 £gm distance between IDT and RGS, a low insertion loss (-40.854 dB) and very high quality factor (Q=206) can be obtained.
Keywords¡Gflexural plate-wave; silicon-trench reflective grating structure; electromechanical coupling coefficient; ZnO; bulk micromachining technology
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Development of Flexural Plate-wave Device with Focused Interdigital Transducers DesignLin, Ji-Yuan 31 July 2012 (has links)
The conventional flexural plate-wave (FPW) device has advantages of high mass sensitivity, low phase velocity and low operation frequency. However, conventional FPW devices usually present a high insertion loss and low fabrication yield. This thesis aimed to reduce the insertion loss of conventional FPW devices. The influences of geometry of inter-digital transducers (IDTs), pair number of IDTs, depth of focus and length of delay line on the insertion loss of FPW device are investigated.
This research utilizes bulk micromachining technique to develop a low insertion-loss FPW device and the main fabrication steps include seven thin-film deposition and four photolithography processes. As the wavelength is 100 £gm, pair number of IDTs is 20, depth of focus is 1000 £gm and length of delay line is 500 £gm, the measured insertion loss of the implemented FPW device with conventional parallel-type IDTs and novel focus-type IDTs are equal to -48 dB and -45.06 dB, respectively. On the other hand, the insertion loss of FPW device with focus-type 25-pairs IDTs (-43.69 dB) is smaller than that of FPW device with focus-type 20-pairs IDTs (-45.06 dB). Additional, the measured insertion loss of FPW device with 500 £gm focus depth (-41.47 dB) is smaller than that of FPW devices with 1000 £gm focus depth (-43.69 dB) or with 1500 £gm focus depth (-45.39 dB). Furthermore, the FPW device with 500 £gm delay line presents a smaller insertion loss (-40.46 dB) than that of FPW devices with 250 £gm delay line (-41.47 dB) or with 750 £gm delay line (-40.95 dB).
Finally, under the optimized specifications (focus-type/25 pairs IDTs, 500 £gm focus depth and 500 £gm delay line), the FPW-based microsensor demonstrates a high sensitivity (91.53 cm2/g), high sensing linearity (99.18 %) and low insertion loss (-40.46 dB), hence it is very suitable for development of biomedical sensing microsystem.
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Development of a Flexural Plate¡Vwave Allergy Biosensor by MEMS TechnologyLee, Ming-Chih 16 August 2012 (has links)
Utilizing self-assembled monolayer nanotechnology, micro-electro-mechanical systems (MEMS) and IC technologies, a novel flexural plate-wave (FPW) biosensor is developed in this dissertation for detecting the immunoglobulin-E (IgE) concentration of human serum. The acoustic waves of the proposed FPW devices are launched by the 25-pair inter-digital transducer (IDT) input electrodes and propagated through the 4.82 £gm-thick Si/SiO2/Si3N4/Cr/Au/ZnO floating thin-plate. Since the thickness of such floating thin-plate is much smaller than the designed wavelength of FPW device (80 £gm), most of the propagating wave energy will not be dissipated into outside of thin-plate and the mass sensitivity is very high. To further reduce the insertion loss of the proposed FPW devices, two 3 £gm-thick Al reflection grating electrodes (RGE) are designed beside the input and output IDTs.
To implement a FPW-based IgE biosensor, a Cr/Au electrode layer has to be deposited on the backside of the floating thin-plate to serve as a substrate for further coating the cystamine SAM/glutaraldehyde/IgE antibody layers. Once the IgE antigens of human serum are bound to the IgE antibody layer, the small change in the mass of floating thin-plate will result in a shift of center frequency of the testing FPW-based biosensor. Compared to the reference FPW biosensors, the shift of center frequency generated by the testing FPW biosensor under different IgE antigen concentration can be detected by commercial network analyzer or the frequency-shift readout system developed by our collaboration laboratory (VLSI Design Lab. of NSYSU).
Compared to commercial enzyme linked immunosorbent assay (ELISA) analyzer (sample volume >25 £gl/well, testing time >60 min, dimension>40 cm ¡Ñ30 cm¡Ñ10 cm), the implemented FPW-based IgE biosensor presents a smaller sample volume (<5 £gl), faster response (<10 min) and smaller size (<9 mm¡Ñ6 mm¡Ñ0.5 mm). In addition, a very low insertion loss (-9.2 dB), a very high mass sensitivity (-6.08¡Ñ109 cm2 g-1) and a very high sensing linearity (99.46 %) of the proposed IgE biosensor can be demonstrated at 6.6 MHz center frequency. This study successfully developed a novel FPW-based allergy biosensor by MEMS technology, which has great potential to be further applied into point-of-care testing (POCT) microsystem.
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Development of FPW-based Mass Sensing Device with Reflection Grating Electrode DesignLai, Yu-zheng 31 August 2009 (has links)
The conventional medical immunoassays (ELISA/CLIA/FPIA) are not only costly (>10,000 USD), large in size (>10,000 cm3), but also require a vast number of sampling (25 £gL/well ¡Ñ 12 well) and long detection time (1~2.5 hr). To develop a biomedical microsensor for the application of portable detecting microsystem, this thesis proposes a flexural plate wave (FPW) microsensor with a novel reflection grating electrode (RGE) microstructure. Comparing to the conventional acoustic microsensors, the FPW based device has higher mass sensitivity, lower operation frequency but higher noise level. To overcome this disadvantages, this study added the RGE microstructure into the design of FPW sensor and investigated its influences on the reduction of insertion loss and noise level.
By using the surface and bulk micromachining technologies, this thesis designed and fabricated FPW-based mass-sensing device with a small volume of 0.189 cm3 and a novel RGE microstructure. The main processing steps adopted in this research include six photolithoghaphies and nine thin-film depositions. In this work, a high figure-of-merit C-axial orientation ZnO piezoelectric thin-film was deposited by a commercial magnetic radio-frequency (RF) sputter system. On the other hand, the gold/chrome interdigital transducer (IDT) and RGE aluminum electrode were deposited utilizing a commercial E-beam evaporator system. For the optimization of design specifications of the FPW devices, the space of input and output IDTs, pair number of IDT, length of delay line gap and with/without RGE design were varied and investigated.
Under the optimized IDT specification, the FPW microstructure presents lower central frequency (2¡ã4 MHz), insertion loss (-11 dB) and noise level (<-30 dB) than that of the FPW based microsensor without RGE microstructure. In addition, as the sampling volume of the testing DI water is equal to 1 £gL, a high mass sensitivity (-48.3 cm2/g) and short responding time (5 min) of the FPW microsensor with RGE design can be achieved in this work. The excellent characteristics mentioned above demonstrated the implemented FPW microsensor is very suitable for the applications of portable biomedical detecting microsystems.
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Study on Electrical and Mechanical Characteristics of Flexural Plate Wave Device-Hung Chen, Yu 02 September 2010 (has links)
Acoustic micro-sensors have already been applied in mass sensing including surface acoustic wave (SAW), flexural plate wave (FPW), thickness shear mode (TSM) and shear horizontal acoustic plate mode (SH-APM). The FPW micro-sensor is very suitable for liquid-sensing and bio-sensing applications due to the high mass-sensitivity and low phase-velocity in liquid. However, the conventional FPW micro-sensors presented a high insertion-loss (IL) and a low signal-to-noise ratio so it is difficult to combine with IC into a micro-system.
To overcome these drawbacks, this study combine the Microelectromechanical System (MEMS) technology and the high C-axis orientation ZnO piezoelectric thin-film to develop a low insertion loss, low operation frequency, and high electromechanical coupling coefficient FPW device. In this study, a high C-axis orientation ZnO piezoelectric thin-film with a 20944A.U. X-Ray diffraction intensity at 34.200 degree and a 0.573 degree full width at half maximum (FWHM) was deposited by a commercial magnetic radio-frequency (RF) sputter system. The total processes of the FPW micro-sensor included five photolithography and seven thin-film depositions. In this study a low operation frequency (0.1MHz), low insertion loss (11dB to 14dB) and high electromechanical coupling coefficient (11%) FPW sensor was developed and fabricated.
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