Abstract
In real-time catheter-based 3-D ultrasound imaging applications, gathering data from the transducer arrays is difficult, as there is a restriction on cable count due to the diameter of the catheter. Although area and power hungry multiplexing circuits integrated at the catheter tip are used in some applications, these are unsuitable for use in small sized catheters for applications, such as intracardiac imaging. Furthermore, the length requirement for catheters and limited power available to on-chip cable drivers leads to limited signal strength at the receiver end. In this paper, an alternative approach using analog time-division multiplexing (TDM) is presented, which addresses the cable restrictions of ultrasound catheters. A novel digital demultiplexing technique is also described, which allows for a reduction in the number of analog signal processing stages required. The TDM and digital demultiplexing schemes are demonstrated for an intracardiac imaging system that would operate in the 4- to 11-MHz range. A TDM integrated circuit (IC) with an 8:1 multiplexer is interfaced with a fast analog-to-digital converter (ADC) through a microcoaxial catheter cable bundle, and processed with a field-programmable gate array register-transfer level simulation. Input signals to the TDM IC are recovered with -40-dB crosstalk between the channels on the same microcoax, showing the feasibility of this system for ultrasound imaging applications.
Highlights
Catheter based real-time 3D imaging, such as used in 3D transesophageal echography (TEE), requires data to be captured from many transducer elements simultaneously to avoid motion artefacts [1]
Cable reduction techniques with electronics complexity, area, and power requirements suitable for integration at the tip of an intracardiac echography (ICE) catheter would have a significant impact in catheter based ultrasound imaging applications, both in terms of implementing large field of view ICE catheters, and by eliminating the need for fluoroscopy
Using the setup explained in VII, several experiments were performed in order to characterize the Time Division Multiplexing (TDM) silicon and the system as a whole
Summary
Catheter based real-time 3D imaging, such as used in 3D transesophageal echography (TEE), requires data to be captured from many transducer elements simultaneously to avoid motion artefacts [1]. Cable reduction techniques with electronics complexity, area, and power requirements suitable for integration at the tip of an ICE catheter would have a significant impact in catheter based ultrasound imaging applications, both in terms of implementing large field of view ICE catheters, and by eliminating the need for fluoroscopy. These techniques can be implemented using monolithic CMUT-on-CMOS, or ICs integrated with CMUT or piezoelectric transducer arrays in a multi-chip package [6] [7] [8] [9]. RealTime Direct Digital Demodulation (DDD) as realized in an FPGA is described and experimental results on the overall system are presented
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