【 摘 要 】

Background

The ultrasonic transducer is one of the core components of ultrasound systems, and the transducer’s sensitivity is significantly related the loss of electronic components such as the transmitter, receiver, and protection circuit. In an ultrasonic device, protection circuits are commonly used to isolate the electrical noise between an ultrasound transmitter and transducer and to minimize unwanted discharged pulses in order to protect the ultrasound receiver. However, the performance of the protection circuit and transceiver obviously degrade as the operating frequency or voltage increases. We therefore developed a crossed SMPS (Switching Mode Power Supply) MOSFET-based protection circuit in order to maximize the sensitivity of high frequency transducers in ultrasound systems.

The high frequency pulse signals need to trigger the transducer, and high frequency pulse signals must be received by the transducer. We therefore selected the SMPS MOSFET, which is the main component of the protection circuit, to minimize the loss in high frequency operation. The crossed configuration of the protection circuit can drive balanced bipolar high voltage signals from the pulser and transfer the balanced low voltage echo signals from the transducer.

Methods

The equivalent circuit models of the SMPS MOSFET-based protection circuit are shown in order to select the proper device components. The schematic diagram and operation mechanism of the protection circuit is provided to show how the protection circuit is constructed. The P-Spice circuit simulation was also performed in order to estimate the performance of the crossed MOSFET-based protection circuit.

Results

We compared the performance of our crossed SMPS MOSFET-based protection circuit with a commercial diode-based protection circuit. At 60 MHz, our expander and limiter circuits have lower insertion loss than the commercial diode-based circuits. The pulse-echo test is typical method to evaluate the sensitivity of ultrasonic transducers. Therefore, we performed a pulse-echo test using a single element transducer in order to utilize the crossed SMPS MOSFET-based protection circuit in an ultrasound system.

Conclusions

The SMPS-based protection circuit could be a viable alternative that provides better sensitivity, especially for high frequency ultrasound applications.

【 授权许可】

   
2014 Choi and Shung; licensee BioMed Central Ltd.

【 预 览 】

附件列表

Files	Size	Format	View
20140705043632665.pdf	1342KB	PDF	download
Figure 7.	107KB	Image	download
Figure 6.	90KB	Image	download
Figure 5.	93KB	Image	download
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Figure 3.	85KB	Image	download
Figure 2.	37KB	Image	download
Figure 1.	78KB	Image	download

【 图 表 】

【 参考文献 】

• [1]Shung KK: Diagnostic ultrasound: Past, present, and future. J Med Biol Eng 2011, 31:371-374.
• [2]Choi H, Li X, Lau S-T, Hu C-H, Zhou Q, Shung KK: Development of integrated preamplifier for high-frequency ultrasonic transducers and low-power handheld receiver. IEEE Trans Ultrason Ferroelectr Freq Control 2011, 58:2646-2658.
• [3]Cannata JM, Williams JA, Zhou Q, Ritter TA, Shung KK: Development of a 35-MHz piezo-composite ultrasound array for medical imaging. IEEE Trans Ultrason Ferroelectr Freq Control 2006, 53:224-236.
• [4]Zhu B, Chan NY, Dai J, Shung KK, Takeuchi S, Zhou Q: New fabrication of high-frequency (100-MHz) ultrasound PZT film kerfless linear array. IEEE Trans Ultrason Ferroelect Freq Control 2013, 60:854-857.
• [5]Qiu W, Yu Y, Tsang FK, Sun L: A multifunctional, reconfigurable pulse generator for high-frequency ultrasound imaging. IEEE Trans Ultrason Ferroelectr Freq Control 2012, 59:1558-1567.
• [6]Supertex Inc: MD0100DB1 High Voltage Protection 8-Channel T/R Switch Demo board. [http://www.supertex.com/pdf/misc/MD0100DB1.pdf webcite]
• [7]Choi H, Shung KK: Novel power MOSFET-based expander for high frequency ultrasound systems. Ultrasonics 2014, 54:121-130.
• [8]Szabo TL: Diagnostic Ultrasound Imaging: Inside Out. Boston: Elsevier Academic Press; 2004.
• [9]International Rectifier: Application Note AN-937, Gate Drive Characteristics and Requirements for HEXFET Power MOSFETs. [http://www.irf.com/technical-info/appnotes/an-937.pdf webcite]
• [10]Blake C, Bull C: IGBT or MOSFET: Choose Wisely. [http://www.irf.com/technical-info/whitepaper/choosewisely.pdf webcite]
• [11]Clemente S, Pelli BR, Isidor A: Understanding HEXFET Switching Performance. [http://application-notes.digchip.com/014/14-15409.pdf webcite]
• [12]Minasian RA: Power MOSFET dynamic large-signal model. Solid-State and Electron Devices, IEE Proceedings I 1983, 130:73-79.
• [13]Colotti J: Analog, RF & EMCconsiderations in printed wiring board design. Proc Long Island Syst Appl and Tech 2005, 16-30. http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1515627 webcite
• [14]Razavi B: RF Microelectronics. Upper Saddle River: Pearson Education; 2003.
• [15]Vuolevi J, Rahkonen T: Distortion in RF Power Amplifiers. Norwood: Artech House; 2003.
• [16]Cripps SC: Advanced Techiques in RF Power Amplifier Design. Norwood: Artech House; 2002.
• [17]Friis HT: Noise figures of radio receivers. Pro of the IRE 1944, 32:419-422.
• [18]Maxim Integrated Products Inc: Three Methods of Noise Figure Measurement. [http://www.maximintegrated.com/en/app-notes/index.mvp/id/2875 webcite]