Abstract: In an underwater acoustic bearing sensor, the vector sensor, heading sensor, and pitch and roll sensor are held in a common mounting ring to ensure that their coordinate systems are collinear. The vector sensor includes x, y, and z accelerometers mounted in the ring and a hydrophone that can be mounted independently.

Abstract: A piezoelectric flexural sensing structure having increased sensitivity and decreased noise, without sacrifice of the sensor bandwidth. The structure is made up of a proof mass, a beam with a base and optionally having castellated bonding surfaces and two <011> poled bonding mode PMN-PT crystal plates mounted on the beam.

Abstract: The present invention is directed to an acoustic vector sensor, also called particle velocity sensor. <111> direction poled, shear mode, relaxor single crystals are used as the sensing elements. In addition, these crystal plates are cut at a special orientation such that they provide zero or minimum responses in the transverse directions, but have a maximum piezoelectric response in sensing direction. The piezoelectric sensor contains a proof mass, a base, and an aforementioned relaxor crystal. Three of the sensors are mounted orthogonally with a rigid case, and they are designated to sense the acoustic particle velocity in three designated directions, say X, Y, and Z. To solve the adverse lateral constraint problem (also known as clamping effect) associated with the relaxor crystal; reduced bonding area between the proof mass and the relaxor crystal are introduced.

Abstract: A sensor includes a piezoelectric hydrophone and at least one accelerometer. In calibration mode, the hydrophone is connected to a source of a known electrical signal and outputs a mechanical/acoustic signal that the accelerometer detects. Comparison of the known electrical signal to the output of the accelerometer allows calibration of the accelerometer. In operation mode, both the hydrophone and the accelerometer are connected to a data acquisition unit.

Abstract: In an underwater acoustic bearing sensor, the vector sensor, heading sensor, and pitch and roll sensor are held in a common mounting ring to ensure that their coordinate systems are collinear. The vector sensor includes x, y, and z accelerometers mounted in the ring and a hydrophone that can be mounted independently.

Abstract: A sensor includes a piezoelectric hydrophone and at least one accelerometer. In calibration mode, the hydrophone is connected to a source of a known electrical signal and outputs a mechanical/acoustic signal that the accelerometer detects. Comparison of the known electrical signal to the output of the accelerometer allows calibration of the accelerometer. In operation mode, both the hydrophone and the accelerometer are connected to a data acquisition unit.

Abstract: A method and apparatus for mechanical strain amplification for enhanced piezoelectric transduction. The device consists of a piezoelectric element elevated above the neutral axis of a supporting, micromachined, photoetched substrate by use of castellations on the substrate. By elevating the piezoelectric element above the neutral axis, the charge sensitivity of the device is increased which facilitates the development of high-sensitivity, low-noise transducers. There is a limit to charge sensitivity because the optimal elevation is a function of the physical properties of the supporting structure and the piezoelectric element. Accordingly, a mathematical formulation and finite element analysis (FEA) are provided to define the optimal height of the castellated substrate. The recognition of limits to the castellation height has further led to the discovery of using the relaxor-ferroelectric, single crystal class of materials in the present invention.