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D.M. van Willigen
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1
In transit-time ultrasonic flow measurement systems, the system's ability to operate reciprocally in the absence of flow is a highly desirable property. If the reciprocity is lacking in the system, any time delay that appears between the upstream and downstream signals at zero-flow conditions will result in false flow measurement. This phenomenon is known as the zero-flow error.
This thesis presents a system in which the reciprocity property has been ensured by matching the electrical impedances of the front-end electronic circuits, namely: the output impedance of the transmitter Z$_\text{out}$ and the input impedance of the receiver Z$_\text{in}$. To achieve this, a circuit has been developed that can be used as both a transmitter and a receiver. This is the main feature that distinguishes the proposed design from those presented in previous work. The transmitter-receiver circuit has been implemented using a three-stage operational amplifier in unity gain feedback configuration. The class AB output stage of the amplifier is equipped with an additional function being used in receive mode for sensing and amplification of the signal. The simulation result obtained by the cross-correlation method yields a zero-flow error value of 30 fs, which is at least by three orders of magnitude smaller than the results achieved in prior work. The input and output impedances are equal to Z$_\text{in}$=73.2$\angle$80.7$^ \text {o}$ m$\Omega$ and Z$_\text{out}$=79.6$\angle$77.3$^ \text {o}$ m$\Omega$ respectively. A small mismatch remaining between the impedances prevents perfect reciprocity to be established in the system. A prototype IC has been taped out in TSMC 0.18 µm BCD Gen2 technology. ...
This thesis presents a system in which the reciprocity property has been ensured by matching the electrical impedances of the front-end electronic circuits, namely: the output impedance of the transmitter Z$_\text{out}$ and the input impedance of the receiver Z$_\text{in}$. To achieve this, a circuit has been developed that can be used as both a transmitter and a receiver. This is the main feature that distinguishes the proposed design from those presented in previous work. The transmitter-receiver circuit has been implemented using a three-stage operational amplifier in unity gain feedback configuration. The class AB output stage of the amplifier is equipped with an additional function being used in receive mode for sensing and amplification of the signal. The simulation result obtained by the cross-correlation method yields a zero-flow error value of 30 fs, which is at least by three orders of magnitude smaller than the results achieved in prior work. The input and output impedances are equal to Z$_\text{in}$=73.2$\angle$80.7$^ \text {o}$ m$\Omega$ and Z$_\text{out}$=79.6$\angle$77.3$^ \text {o}$ m$\Omega$ respectively. A small mismatch remaining between the impedances prevents perfect reciprocity to be established in the system. A prototype IC has been taped out in TSMC 0.18 µm BCD Gen2 technology. ...
In transit-time ultrasonic flow measurement systems, the system's ability to operate reciprocally in the absence of flow is a highly desirable property. If the reciprocity is lacking in the system, any time delay that appears between the upstream and downstream signals at zero-flow conditions will result in false flow measurement. This phenomenon is known as the zero-flow error.
This thesis presents a system in which the reciprocity property has been ensured by matching the electrical impedances of the front-end electronic circuits, namely: the output impedance of the transmitter Z$_\text{out}$ and the input impedance of the receiver Z$_\text{in}$. To achieve this, a circuit has been developed that can be used as both a transmitter and a receiver. This is the main feature that distinguishes the proposed design from those presented in previous work. The transmitter-receiver circuit has been implemented using a three-stage operational amplifier in unity gain feedback configuration. The class AB output stage of the amplifier is equipped with an additional function being used in receive mode for sensing and amplification of the signal. The simulation result obtained by the cross-correlation method yields a zero-flow error value of 30 fs, which is at least by three orders of magnitude smaller than the results achieved in prior work. The input and output impedances are equal to Z$_\text{in}$=73.2$\angle$80.7$^ \text {o}$ m$\Omega$ and Z$_\text{out}$=79.6$\angle$77.3$^ \text {o}$ m$\Omega$ respectively. A small mismatch remaining between the impedances prevents perfect reciprocity to be established in the system. A prototype IC has been taped out in TSMC 0.18 µm BCD Gen2 technology.
This thesis presents a system in which the reciprocity property has been ensured by matching the electrical impedances of the front-end electronic circuits, namely: the output impedance of the transmitter Z$_\text{out}$ and the input impedance of the receiver Z$_\text{in}$. To achieve this, a circuit has been developed that can be used as both a transmitter and a receiver. This is the main feature that distinguishes the proposed design from those presented in previous work. The transmitter-receiver circuit has been implemented using a three-stage operational amplifier in unity gain feedback configuration. The class AB output stage of the amplifier is equipped with an additional function being used in receive mode for sensing and amplification of the signal. The simulation result obtained by the cross-correlation method yields a zero-flow error value of 30 fs, which is at least by three orders of magnitude smaller than the results achieved in prior work. The input and output impedances are equal to Z$_\text{in}$=73.2$\angle$80.7$^ \text {o}$ m$\Omega$ and Z$_\text{out}$=79.6$\angle$77.3$^ \text {o}$ m$\Omega$ respectively. A small mismatch remaining between the impedances prevents perfect reciprocity to be established in the system. A prototype IC has been taped out in TSMC 0.18 µm BCD Gen2 technology.
Master thesis
(2019)
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Rishabh Nitin Nagarkar, Michiel Pertijs, Douwe van Willigen, Qinwen Fan, Marco Spirito
An ASIC is presented for intra-vascular ultrasound imaging. Despite being connected via a single coaxial cable, it is able to pass arbitrary high voltage bipolar signals to the transducers for acoustic imaging. The thesis talks about the need to reduce the cable count to one and reviews the existing work in literature. It builds up on an existing single cable design and focuses on the transmit part to make it compatible to a large number of ultrasound imaging modes by allowing it to pass high frequency signals up to 20MHz and bipolar signal voltages up to ±25V . The chip is phantom powered and thus its power supply and signals are transmitted on the same cable. The transmit switch designed for this ASIC is powered by and controlled by an on-chip low voltage supply and circuitry. The prototype ASIC has been designed in TSMC 180nm HV BCD Gen2 technology. This single cable design has 16 elements for transmit and 64 elements in the receive mode and was evaluated using simulations.
...
An ASIC is presented for intra-vascular ultrasound imaging. Despite being connected via a single coaxial cable, it is able to pass arbitrary high voltage bipolar signals to the transducers for acoustic imaging. The thesis talks about the need to reduce the cable count to one and reviews the existing work in literature. It builds up on an existing single cable design and focuses on the transmit part to make it compatible to a large number of ultrasound imaging modes by allowing it to pass high frequency signals up to 20MHz and bipolar signal voltages up to ±25V . The chip is phantom powered and thus its power supply and signals are transmitted on the same cable. The transmit switch designed for this ASIC is powered by and controlled by an on-chip low voltage supply and circuitry. The prototype ASIC has been designed in TSMC 180nm HV BCD Gen2 technology. This single cable design has 16 elements for transmit and 64 elements in the receive mode and was evaluated using simulations.