Abstract: A toxic gas sensor or device which is a cavity ring-down spectroscopy device having two or more mirror components. Each of the mirror components has two Brewster windows attached to it. The Brewster windows are resistant to toxic gases and together with the respective mirror form a hermetically sealed volume for the mirror surface to protect it from the environment or test gases. The Brewster windows may have a heating mechanism to remove contaminants, condensation, and provide temperature stabilization and other beneficial features.

Abstract: A vibration isolator device for printed wiring boards. An example vibration isolator device includes a solder tab with an elastomeric material that is adhesively attached to a first side of the solder tab. The second side of the solder tab is attached to a printed wiring board. Solder paste is pre-applied to the printed wiring board prior to attachment of the vibration isolator device. The solder tab has a U-shaped cross section.

Abstract: Structures and methods for frequency shifting rotational harmonics in MEMS devices are disclosed. An illustrative MEMS device can include a substrate, a sense electrode coupled to the substrate, and a proof mass adjacent to the sense electrode. A number of non-uniformly dispersed holes or openings on the proof mass can be configured to alter the distribution of mass within the proof mass. During operation, the presence of the holes or openings alters the frequency at which the proof mass rotates about a centerline in a rotational mode, reducing the introduction of harmonics into the drive and sense systems.

Abstract: A system and method for determining acceleration along a motor axis of a MEMS gyroscope includes a processor. The processor includes a notch filter to remove a sinusoid from an instantaneous voltage from a motor pick up of the MEMS gyroscope. A memory bus allows random access to data stored in a processor readable memory. A processor-readable memory in operative engagement with the memory bus allows access to the processor-readable memory containing data. The data includes a model relating at least one instantaneous voltage in a remaining instantaneous voltage to an acceleration of a proof mass along the motor axis. Instructions to the processor include a routine to compare the at least one instantaneous voltage in the model to the remaining instantaneous voltage.

Abstract: A system and method for deriving an angular rate includes receiving a motor pick off signal received from a motor pick off of from a MEMS gyroscope. Receiving a sensing pick off signal received from a sensing pick off from the MEMS gyroscope allows the determining of a phase relationship between the motor pick off signal and the sensing pick off signal. Determining an angular rate is based upon an amplitude of the sensing pick off signal. Determining the whether the sign of the rotational rate is positive or negative is based upon the phase relationship of the sensing pick off signal from a MEMS gyroscope relative to the motor pick off signal received from the motor pick off.

Abstract: A method of bonding and packaging components of Micro-Electro-Mechanical Systems (MEMS) and MEMS based devices using a Solid-Liquid InterDiffusion (SLID) process is provided. A micro-machine is bonded to a micro-machine chip using bonding materials. A layer of chromium is first deposited onto surfaces of the micro-machine and the micro-machine chip followed by a layer of gold. Subsequently, a layer of indium is deposited between the layers of gold, and the surface of the micro-machine is pressed against the surface of the micro-machine chip forming a gold-indium alloy to serve as a bond between the micro-machine and the micro-machine chip. In addition, a cover is bonded to the micro-machine chip in the same manner providing a hermetic seal for the MEMS based device.

Abstract: By applying a first value of voltage to a first side of a MEMS gyroscope and applying a second value of voltage to a second side of the MEMS gyroscope, the start time of the MEMS gyroscope may be improved. The first and second value of voltage may be provided by a bias power source, such as a battery or a super capacitor. The first value of voltage may be substantially equal in magnitude to and opposite in polarity to the second value of voltage. The bias power source may also be applied to drive electronics connected to the MEMS gyroscope. The bias power source may prevent amplifiers within the drive electronics from saturating during the start time.

Abstract: A method for providing micro-electromechanical systems (MEMS) devices with multiple motor frequencies and uniform motor-sense frequency separation is described. The devices each include at least one proof mass, each proof mass being connected to a substrate by a system of suspensions. The method includes controlling the resonant frequencies of the MEMS device by adjusting at least two of a mass of the proof masses, a bending stiffness of the proof masses, a length of the suspensions, and a width of the suspensions.

Abstract: A micro-electromechanical systems (MEMS) device is described which includes a substrate having at least one anchor, a proof mass having either of at least one deceleration extension extending from the proof mass or at least one deceleration indentation formed in the proof mass, a motor drive comb, and a motor sense comb. The MEMS device further includes a plurality of suspensions configured to suspend the proof mass over the substrate and between the motor drive comb and the motor sense comb, and the suspensions are anchored to the substrate. The MEMS device also includes a body attached to the substrate and at least one deceleration beam extending from the body. The deceleration extensions are configured to engage either deceleration beams or deceleration indentations and slow or stop the proof mass before it contacts either of the motor drive comb or the motor sense comb.

Abstract: A method for reducing undesired movements of proof masses in micro-electromechanical systems (MEMS) devices is described where the proof masses are suspended above a substrate by one or more suspensions. The method includes providing an anchor on the substrate substantially between a first proof and suspensions for the first proof mass and a second proof mass and suspensions for the second proof mass, coupling a first portion of a beam to the first proof mass, coupling a second portion of the beam to the second proof mass, and attaching a third portion of the beam to the anchor, the third portion extending between the first portion and second portion of the beam, the anchor and the third portion configured to allow for rotation about an axis perpendicular to the substrate.

Abstract: A MEMS gyroscope system and method for increasing a dynamic range of the MEMS gyroscope is provided. By adjusting a scale factor of the MEMS gyroscope, the highest sensed rate will be increased, which increases the dynamic range. The scale factor may be adjusted by using a variable sense bias and/or an automatic gain control loop in sense electronics.

Abstract: A method of bonding and packaging components of Micro-Electro-Mechanical Systems (MEMS) and MEMS based devices using a Solid-Liquid InterDiffusion (SLID) process is provided. A micro-machine is bonded to a micro-machine chip using bonding materials. A layer of chromium is first deposited onto surfaces of the micro-machine and the micro-machine chip followed by a layer of gold. Subsequently, a layer of indium is deposited between the layers of gold, and the surface of the micro-machine is pressed against the surface of the micro-machine chip forming a gold-indium alloy to serve as a bond between the micro-machine and the micro-machine chip. In addition, a cover is bonded to the micro-machine chip in the same manner providing a hermetic seal for the MEMS based device.

Abstract: A method for reducing effects of common mode oscillations between two respective proof masses in micro-electromechanical systems (MEMS) devices is described. The MEMS devices also include a motor pickoff comb, a sense plate, and a motor drive comb for each proof mass. The method includes amplifying signals received from respective motor pickoff combs, inverting the amplified signal from one of the motor pickoff combs, and generating a difference signal between the inverted, amplified signal from one pickoff comb, and the non-inverted, amplified signal from the other pickoff comb. The method also includes inputting the difference signal into a control loop and generating motor drive signals for respective motor drive combs with the control loop.

Abstract: By applying a first value of voltage to a first side of a MEMS gyroscope and applying a second value of voltage to a second side of the MEMS gyroscope, the start time of the MEMS gyroscope may be improved. The first and second value of voltage may be provided by a bias power source, such as a battery or a super capacitor. The first value of voltage may be substantially equal in magnitude to and opposite in polarity to the second value of voltage. The bias power source may also be applied to drive electronics connected to the MEMS gyroscope. The bias power source may prevent amplifiers within the drive electronics from saturating during the start time.

Abstract: A method of bonding and packaging components of Micro-Electro-Mechanical Systems (MEMS) and MEMS based devices using a Solid-Liquid InterDiffusion (SLID) process is provided. A micro-machine is bonded to a micro-machine chip using bonding materials. A layer of chromium is first deposited onto surfaces of the micro-machine and the micro-machine chip followed by a layer of gold. Subsequently, a layer of indium is deposited between the layers of gold, and the surface of the micro-machine is pressed against the surface of the micro-machine chip forming a gold-indium alloy to serve as a bond between the micro-machine and the micro-machine chip. In addition, a cover is bonded to the micro-machine chip in the same manner providing a hermetic seal for the MEMS based device.

Abstract: By injecting noise into drive electronics, the start time of the MEMS gyroscope may be improved. A noise source is used to provide bandwidth limited white noise with a bandwidth centered substantially at the tuning fork frequency of at least one proof mass.

Abstract: A method for reducing undesired movements of proof masses in micro-electromechanical systems (MEMS) devices is described where the proof masses are suspended above a substrate by one or more suspensions. The method includes providing an anchor on the substrate substantially between a first proof and suspensions for the first proof mass and a second proof mass and suspensions for the second proof mass, coupling a first portion of a beam to the first proof mass, coupling a second portion of the beam to the second proof mass, and attaching a third portion of the beam to the anchor, the third portion extending between the first portion and second portion of the beam, the anchor and the third portion configured to allow for rotation about an axis perpendicular to the substrate.

Abstract: A method for providing micro-electromechanical systems (MEMS) devices with multiple motor frequencies and uniform motor-sense frequency separation is described. The devices each include at least one proof mass, each proof mass being connected to a substrate by a system of suspensions. The method includes controlling the resonant frequencies of the MEMS device by adjusting at least two of a mass of the proof masses, a bending stiffness of the proof masses, a length of the suspensions, and a width of the suspensions.

Abstract: By applying a first value of voltage to a first side of a MEMS gyroscope and applying a second value of voltage to a second side of the MEMS gyroscope, the start time of the MEMS gyroscope may be improved. The first and second value of voltage may be provided by a bias power source, such as a battery or a super capacitor. The first value of voltage may be substantially equal in magnitude to and opposite in polarity to the second value of voltage. The bias power source may also be applied to drive electronics connected to the MEMS gyroscope. The bias power source may prevent amplifiers within the drive electronics from saturating during the start time.

Abstract: A method for reducing effects of common mode oscillations between two respective proof masses in micro-electromechanical systems (MEMS) devices is described. The MEMS devices also include a motor pickoff comb, a sense plate, and a motor drive comb for each proof mass. The method includes amplifying signals received from respective motor pickoff combs, inverting the amplified signal from one of the motor pickoff combs, and generating a difference signal between the inverted, amplified signal from one pickoff comb, and the non-inverted, amplified signal from the other pickoff comb. The method also includes inputting the difference signal into a control loop and generating motor drive signals for respective motor drive combs with the control loop.