Micromachined ultrasonic transducers (MUTs) continue to develop as technological elements for machine-human interface and healthcare applications. Recent advances in micro-fabrication technology and techniques have resulted in wider and innovative applications for pMUTs as limitations such as critical dimensions have been resolved to an appreciable stage. Unlike capacitive micromachined ultrasonic transducers (cMUTs), pMUTs do not require high DC polarization voltages and small capacitive gaps, which reduces complexity of driving circuitry and fabrication. In the present invention, a method of electrically addressing elements of a piezoelectric micromachined ultrasonic transducer (pMUT) in a two dimensional array with minimal number of electrical contacts was described by addressing a row and column selection line for each element using only top electrode patterning.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Typically pMUT arrays have few elements (less than 100 vibrating membranes) and as such, connecting each membrane to the corresponding driving circuitry is achieved with wirebonding, flip-chip bonding or any other one-to-one correspondence of each membrane electrode pair to driving electronics. For integration of a large number of membranes for advanced, high resolution ultrasonic imaging, the number of required connection can be too complex and cumbersome for direct implementation. In those cases, a row/column addressing of each acoustic pixel is more feasible and less complex. For the definition of the piezoelectric actuated membranes, it may be convenient not to pattern the bottom electrode of the pMUT, as it may interfere with the crystalline quality of the thin film, which in turn affects the piezoelectric coefficients of the piezoelectric layer. This imposes an extra difficulty on implementing the row/column addressing in a dense pMUT array.
An embodiment is a method for designing an ultrasonic transducer (UT) array that can be dynamically addressed by two or more top electrodes, organized as row pin selector and column selector, turning on/off any element that is selected by the row/column selector electronic circuitry. The bottom electrode is a single electrode that is not patterned. This method of addressing individual pMUT elements in denser arrays provides for the use of limited electrical contacts. A driving electronic circuit including a row and column selector, at least on electronic circuit oscillator, which may be tunable or not, and amplifiers for signal conditioning may be connected to the UT array, either from an on-chip electronic circuitry, a different electronic chip connected to the UT array chip or from a chip or discrete electronic components mounted on an external board. In a further embodiment, the fabrication of a complex 2D beamforming ultrasonic array is enabled to increase the number of independently actuated transducer count from 4 to thousands of elements.
In yet another embodiment of this invention relates to a design of top metallization layer (or layers) in order to route the electrical connections for row/column addressing, where microelectro-mechanical systems (MEMS) based piezo machined ultrasonic transducers (PMUT) are arranged in complex arrays of column and row based electrical signal driving. An ultrasonic transducer capable of generating and detecting acoustic waves, consisting of a piezoelectric deformable layer between two or more electrodes and surrounded by structural thin-film or films forming a suspended membrane. The top electrodes are used to transmit the ultrasonic wave using an electrical signal. The individual pMUT of an array is addressed through phase shifted voltage signals. The membrane can be either clamped or possessing holes, where the shape is circular, rectangular, square, or any other two-dimensional shape.
In reference to the drawings, the reference numerals designate identical or corresponding parts throughout the several views.
The piezoelectric layer is deposited onto a membrane which is fabricated using techniques of microfabrication known in the art. As such a suspended membrane can mechanically deform and oscillate if a time-varying electrical signal is applied to the pMUT electrodes. Reciprocally, if an oscillating mechanical force, such as an acoustic pressure, is applied to the membrane, this will vibrate and in turn a time-varying electrical signal will be detected at the electrodes. In order to obtain high crystalline quality, with low defect density piezoelectric material it is important to maintain a continuous bottom electrode made of a metal with the suitable microscopic properties for the growth of crystalline layer with matching lattice parameters.
In the present embodiment, pMUT devices were patterned on the top electrode while the bottom electrode was not patterned in the pMUT devices. Specifically, as bottom electrode patterning is detrimental to the device performance, affecting the quality of the piezoelectric layer. As such the bottom electrode covers all the bottom surface of the microchip where the pMUT array is manufactured and was be electrically grounded for reduction of the cross-talk between the different elements of the array. At least two top electrodes are defined on the top of the piezoelectric layer of the pMUT with at least one being driving by the row electrical signal and at least one driven by the column electrical signal. The electrodes are made of electrical conductive materials, typically but not limited to metals. Examples of such metals are molybdenum, aluminum, nickel, platinum, titanium, cobalt, tungsten, and similar metals.
By using electric bipolar signals, the row and column top electrodes are set at opposite polarities (180° phase shift of equal level signals) turning off the vibration of the membrane. If both signals have the same polarity and level (0° phase shift) the piezoelectric induced vibration will be induced on that element. Further, by using the opposite polarity mode and a driving frequency corresponding the resonance of the higher mode of the membrane that matches the vibration pattern of the out-of-phase dual electrode configuration, the operation frequency of the pMUT was changeable.
In the three electrode configuration, a fundamental mode (also known as first mode) is obtained for the following conditions. First, the driving voltage/current source is sinusoidal with a frequency corresponding to the first mode of the membrane, and second, the AC driving voltage is applied to both top electrodes with a phase difference of 0 (zero) degrees or the AC driving signal is applied to only one of the electrodes, for which condition, the dynamic displacement will be half of that obtained from driving the two top electrodes in phase. If the two top electrodes are out of phase by 180 degrees, the vibration is heavy damped, with no displacement measurable, therefore shutting down the mechanical oscillation even with a voltage signal applied to both top electrodes. Advanced beamforming patterns are formed by two dimensional addressing of dense (more than 256×256 element) pMUT arrays.
In
The CMOS layer is represented as the bottom layer in
For an N×N array, instead of N2 contacts, only 2N are needed. Another benefit of this design is a high contrast on-off ratio without floating grounds/signals inducing residual piezoelectric to mechanical transduction.
In one embodiment, a three electrode configuration of the fabricated pMUT is shown in
For fabrication, aluminum nitride (AIN) was used as the active piezoelectric layer with a thickness of 111 m, positioned between two molybdenum electrodes (0.2 11 m thick each) and deposited over a 6 11 m silicon passive membrane layer. The 200 11 m radius membrane was released by backside DRIE etch. The top electrode diameter was 65% of the total device diameter that further divided in two halves, with each connected to a different electrical connecting pad. The bottom electrode was not patterned and covers fully the bottom side of the membrane.
The interferogram depicted in
The configuration was developed into the different models represented in
For more complex arrays,
Further aspects of the invention will be brought out in the following portions of the specification, wherein the detailed description is for the purpose of fully disclosing preferred embodiments of the invention without placing limitations thereon.
Number | Date | Country | |
---|---|---|---|
62330881 | May 2016 | US |