Abstract: A stylet for inserting an electrode array into a cochlea includes a first sensor insertable within a lumen of the electrode array and sensitive to force applied by a lumen wall to the first sensor and a first actuator adapted to move the electrode array in response to the force sensed by the first sensor.

Abstract: A stylet for inserting an electrode array into a cochlea includes a first sensor insertable within a lumen of the electrode array and sensitive to force applied by a lumen wall to the first sensor and a first actuator adapted to move the electrode array in response to the force sensed by the first sensor.

Abstract: A method for calibrating a computer program that simulates a physical process and a photomask are disclosed. A first physical artifact may be exposed to the physical process to produce a second physical artifact. The first physical artifact may include one or more features characterized by traceably measured known dimensions. One or more features of the second physical artifact may be measured to produce one or more measured dimensions. The physical process may be simulated with a computer simulation using the known dimensions of the first physical artifact as inputs to produce an output. The output may be compared to the measured dimensions of the second physical artifact to produce a result. A figure of merit may be assigned to the computer simulation based on the result. The photomask may have one or more features with one or more traceably measured dimensions.

Abstract: A method for calibrating a computer program that simulates a physical process and a photomask are disclosed. A first physical artifact may be exposed to the physical process to produce a second physical artifact. The first physical artifact may include one or more features characterized by traceably measured known dimensions. One or more features of the second physical artifact may be measured to produce one or more measured dimensions. The physical process may be simulated with a computer simulation using the known dimensions of the first physical artifact as inputs to produce an output. The output may be compared to the measured dimensions of the second physical artifact to produce a result. A figure of merit may be assigned to the computer simulation based on the result. The photomask may have one or more features with one or more traceably measured dimensions.

Abstract: A stylet for inserting an electrode array into a cochlea includes a first sensor insertable within a lumen of the electrode array and sensitive to force applied by a lumen wall to the first sensor and a first actuator adapted to move the electrode array in response to the force sensed by the first sensor.

Abstract: Calibration of measurements of features made with a system having a micromachining tool and an analytical tool is disclosed. The measurements can be calibrated with a standard having a calibrated feature with one or more known dimensions. The standard may have one or more layers including a single crystal layer. The calibrated feature may include one or more vertical features characterized by one or more known dimensions and formed through the single crystal layer. A trench is formed in a sample with the micromachining tool to reveal a sample feature. The analytical tool measures one or more dimensions of the sample feature corresponding to one or more known dimensions of the calibrated feature. The known dimensions of the calibrated feature are measured with the same analytical tool. The measured dimensions of the sample feature and the calibrated feature can then be compared to the known dimensions of the calibrated feature.

Abstract: A calibration standard, for calibrating lateral or angular dimensional measurement systems, is provided. The standard may include a first substrate spaced from a second substrate. The standard may be cross-sectioned in a direction substantially perpendicular or substantially non-perpendicular to an upper surface of the first substrate. The cross-sectioned portion of the standard may form a viewing surface of the calibration standard. The standard may include at least one layer disposed between the first and second substrates. The layer, or a feature etched into the first or second substrate or a feature etched into the layer may have a traceably measured thickness or may be oriented at a traceably measured angle with respect to the viewing surface. A thickness or angle of the layer or other feature may be traceably measured using any technique for calibrating a measurement system with a standard reference material traceable to a national testing authority.

Abstract: In one embodiment, an atomic force microscope comprises a frame, a beam coupled to the frame at a first end and a second end, a probe mounted to the beam, means for inducing relative motion between the beam and an underlying surface, and means for detecting a characteristic of the beam.

Abstract: Calibration of measurements of features made with a system having a micromachining tool and an analytical tool is disclosed. The measurements can be calibrated with a standard having a calibrated feature with one or more known dimensions. The standard may have one or more layers including a single crystal layer. The calibrated feature may include one or more vertical features characterized by one or more known dimensions and formed through the single crystal layer. A trench is formed in a sample with the micromachining tool to reveal a sample feature. The analytical tool measures one or more dimensions of the sample feature corresponding to one or more known dimensions of the calibrated feature. The known dimensions of the calibrated feature are measured with the same analytical tool. The measured dimensions of the sample feature and the calibrated feature can then be compared to the known dimensions of the calibrated feature.

Abstract: In one embodiment, an atomic force microscope comprises a frame, a beam coupled to the frame at a first end and a second end, a probe mounted to the beam, means for inducing relative motion between the beam and an underlying surface, and means for detecting a characteristic of the beam.

Abstract: A calibration standard, for calibrating lateral or angular dimensional measurement systems, is provided. The standard may include a first substrate spaced from a second substrate. The standard may be cross-sectioned in a direction substantially perpendicular or substantially non-perpendicular to an upper surface of the first substrate. The cross-sectioned portion of the standard may form a viewing surface of the calibration standard. The standard may include at least one layer disposed between the first and second substrates. The layer, or a feature etched into the first or second substrate or a feature etched into the layer may have a traceably measured thickness or may be oriented at a traceably measured angle with respect to the viewing surface. A thickness or angle of the layer or other feature may be traceably measured using any technique for calibrating a measurement system with a standard reference material traceable to a national testing authority.

Abstract: A process and structure for mounting a small sample in an opening in a larger substrate by using an intermediate size structure, wherein the small sample is mounted in a small opening in the intermediate size structure which then, in turn, is mounted in an intermediate size opening in the large substrate. As a result, the formation of gaps around the edge of the sample may be voided. The process is carried out by first mounting the test sample in a opening formed with tapered sidewalls through a die with the upper surface of the sample directly abutting the edges of the smallest portion of the tapered opening in the die, The die is then mounted in an opening with tapered sidewalls in a test wafer. The opening in the die is sized to equal, at the smallest end of the tapered sidewalls of the opening, the width and length of the square sample.

Abstract: A calibration standard which may be used to calibrate lateral dimensional measurement systems is provided. The calibration standard may include a first substrate spaced from a second substrate. In addition, the calibration standard may include at least one layer disposed between the first and second substrates. The layer may have a traceably measured thickness. For example, a thickness of the layer may be traceably measured using any measurement technique in which a measurement system may be calibrated with a standard reference material traceable to a national testing authority. The calibration standard may be cross-sectioned in a direction substantially perpendicular to an upper surface of the first substrate. The cross-sectioned portion of the calibration standard may form a viewing surface of the calibration standard. In this manner, a lateral dimensional artifact of the calibration standard may include the traceably measured thickness of at least the one layer.

Abstract: A calibration standard which may be used to calibrate lateral dimensional measurement systems is provided. The calibration standard may include a first substrate spaced from a second substrate. In addition, the calibration standard may include at least one layer disposed between the first and second substrates. The layer may have a traceably measured thickness. For example, a thickness of the layer may be traceably measured using any measurement technique in which a measurement system may be calibrated with a standard reference material traceable to a national testing authority. The calibration standard may be cross-sectioned in a direction substantially perpendicular to an upper surface of the first substrate. The cross-sectioned portion of the calibration standard may form a viewing surface of the calibration standard. In this manner, a lateral dimensional artifact of the calibration standard may include the traceably measured thickness of at least the one layer.

Abstract: A scanning mechanism is provided for use in a scanning probe microscope. The scanning mechanism includes a stationary portion; a moveable portion; a plurality of springs attaching the moveable portion to the fixed portion, the plurality of springs providing tension against movement of the moveable portion relative to the stationary portion, the tension provided by the plurality of springs having a substantially linear spring constant over a scan distance; and one or more voice coils attached to either the moveable portion or the stationary portion for moving the moveable portion relative to the stationary portion in one or more orthogonal directions.

Abstract: Atomic force microscope system is provided which is designed to be incorporated into or attachable to an objective lens which can be mounted on a lens turret of an optical microscope such that simultaneous atomic force microscopy and optical viewing of a sample through the objective lens can be performed. In one embodiment, the atomic force microscope (AFM) is designed to be removably attached to a standard objective lens of an optical microscope. In another embodiment, the AFM system is designed to be removably attached to an optical microscope and includes integrated optics for providing an optical view. In both embodiments, the optics are used solely for generating an optical view and/or other optical contrast mechanisms and are not used in conjunction with a detection mechanism of the AFM.

Abstract: Atomic force microscope system is provided which is designed to be incorporated into or attachable to an objective lens which can be mounted on a lens turret of an optical microscope such that simultaneous atomic force microscopy and optical viewing of a sample through the objective lens can be performed. In one embodiment, the atomic force microscope (AFM) is designed to be removably attached to a standard objective lens of an optical microscope. In another embodiment, the AFM system is designed to be removably attached to an optical microscope and includes integrated optics for providing an optical view. In both embodiments, the optics are used solely for generating an optical view and/or other optical contrast mechanisms and are not used in conjunction with a detection mechanism of the AFM.

Abstract: Atomic force microscope system is provided which is designed to be incorporated into or attachable to an objective lens which can be mounted on a lens turret of an optical microscope such that simultaneous atomic force microscopy and optical viewing of a sample through the objective lens can be performed. In one embodiment, the atomic force microscope (AFM) is designed to be removably attached to a standard objective lens of an optical microscope. In another embodiment, the AFM system is designed to be removably attached to an optical microscope and includes integrated optics for providing an optical view. In both embodiments, the optics are used solely for generating an optical view and/or other optical contrast mechanisms and are not used in conjunction with a detection mechanism of the AFM.

Abstract: A microminiature cantilever structure is provided having a cantilever arm with a piezoresistive resistor embedded in at least the fixed end of the cantilever arm. Deflection of the free end of the cantilever arm produces stress in the base of the cantilever. That stress changes the piezoresistive resistor's resistance at the base of the cantilever in proportion to the cantilever arm's deflection. Resistance measuring apparatus is coupled to the piezoresistive resistor to measure its resistance and to generate a signal corresponding to the cantilever arm's deflection. The microminiature cantilever is formed on a semiconductor substrate. A portion of the free end of the cantilever arm is doped to form an electrically separate U-shaped piezoresistive resistor. The U-shaped resistor has two legs oriented parallel to an axis of the semiconductor substrate having a non-zero piezoresistive coefficient.

Abstract: A microminiature cantilever structure is provided having a cantilever arm with a piezoresistive resistor embedded in at least the fixed end of the cantilever arm. Deflection of the free end of the cantilever arm produces stress in the base of the cantilever. That stress changes the piezoresistive resistor's resistance at the base of the cantilever in proportion to the cantilever arm's deflection. Resistance measuring apparatus is coupled to the piezoresistive resistor to measure its resistance and to generate a signal corresponding to the cantilever arm's deflection. The microminiature cantilever is formed on a semiconductor substrate. A portion of the free end of the cantilever arm is doped to form an electrically separate U-shaped piezoresistive resistor. The U-shaped resistor has two legs oriented parallel to an axis of the semiconductor substrate having a non-zero piezoresistive coefficient.