Abstract: Provided is an ultrasonic sensor assembly. The present invention simplifies an assembly structure of the ultrasonic sensor assembly, and thus enables a process of the ultrasonic sensor assembly to be performed as an automation process.

Abstract: A transducer device includes first and second resonant elements and a common coupling cavity. The first resonant element includes a first membrane arranged over a first cavity in a substrate and a first transducer structure stacked on the first membrane. The second resonant element includes a second membrane arranged over a second cavity in the substrate. The common coupling cavity is configured to couple acoustic signals from the first and second resonant elements.

Abstract: The vibrating reed includes a first main surface and a second main surface that face each other in the thickness direction of a piezoelectric body and a detection unit that vibrates along the thickness direction when detecting. The detection unit includes a groove of which a groove bottom is positioned at a position beyond a midplane between the first main surface and the second main surface in the depth direction from an opening formed in the first main surface, an inside surface electrode that is formed on an inside surface facing the inside of the groove, an outside surface electrode that is formed on an outside surface which is opposite the inside surface with the piezoelectric body interposed therebetween, and a pair of groove bottom electrodes that is provided further on the groove bottom at an interval than the midplane and face inside the groove.

Abstract: A vibration test fixture includes a shaker and a slip plate coupled with the shaker. A mounting plate may be coupled with the slip plate and a cylindrical bridge may be coupled with the mounting plate. A sensor may be coupled with the bridge.

Abstract: The invention relates to a micromechanical sensor having at least two spring-mass damper oscillators. The micromechanical sensor has a first spring-mass-damper oscillating system with a first resonant frequency and a second spring-mass-damper oscillating system with a second resonant frequency which is lower than the first resonant frequency. The invention also relates to a method for detection and/or measurement of oscillations by means of a sensor such as this, and to a method for production of a micromechanical sensor such as this. The first and the second spring-mass-damper oscillating systems have electrodes which oscillate in a measurement direction about electrode rest positions with electrode deflections which are equal to or proportional to deflections of the spring-mass-damper oscillators.

Abstract: Provided is a device capable of easily and accurately detecting a vibration period when, for example, an earthquake occurs. When a quartz-crystal plate bends upon application of a force, capacitance between a movable electrode provided at its tip portion and a fixed electrode provided on a vessel to face the movable electrode changes, so that an oscillation frequency of the quartz-crystal plate changes according to this capacitance. Therefore, when the vessel is vibrated, there appear a first state where the quartz-crystal plate ends to approach the fixed electrode and a second state where the quartz-crystal plate is in an original state or bends to be apart from the fixed electrode. Accordingly, an oscillation frequency corresponding to the first state and corresponding to the second state alternately appear, and therefore, it is possible to find the period (frequency) of the vibration.

Abstract: Provided is a device capable of easily and accurately detecting a vibration period when, for example, an earthquake occurs. When a quartz-crystal plate bends upon application of a force, capacitance between a movable electrode provided at its tip portion and a fixed electrode provided on a vessel to face the movable electrode changes, so that an oscillation frequency of the quartz-crystal plate changes according to this capacitance. Therefore, when the vessel is vibrated, there appear a first state where the quartz-crystal plate ends to approach the fixed electrode and a second state where the quartz-crystal plate is in an original state or bends to be apart from the fixed electrode. Accordingly, an oscillation frequency corresponding to the first state and corresponding to the second state alternately appear, and therefore, it is possible to find the period (frequency) of the vibration.

Abstract: A vibratory sensor includes a resonator element including (i) a first base portion and a second base portion, each ot the first and the second base portions having an upper main surface and a lower main surface, (ii) a resonating arm extended in a beam shape between the first and the second base portions to be vibrated at a predetermined resonance frequency, (iii) a first narrow portion formed by reducing a width of a portion extended from the first base portion to be smaller than a width of the first base portion in a direction orthogonal to an extending direction of the resonating arm, (iv) a second narrow portion formed by reducing a width of a portion extended from the second base portion to be smaller than a width of the second base portion in the direction orthogonal to the extending direction of the resonating arm, (v) a first support portion extended from the first narrow portion in a direction opposite to the first base portion, and (vi) a second support portion extended from the second narrow portio

Abstract: The invention relates to a vibration measurement system for frequency-selective oscillation measurement in particular of low frequencies as are relevant in the field of automation and drive technology. The invention proposes coupling a broadband transmitter structure, which is excited directly by the excitation signal to be determined, via an electrostatic or inductive force to a receiver structure. This force coupling results in amplitude modulation of a carrier signal exciting the receiver structure. The actual excitation signal can be extracted from the spectrum of the amplitude-modulated carrier signal, for example by suitably selecting the frequency of the carrier signal. In order to make an oscillation analysis possible which is as unsusceptible to interference possible, an interference signal brought about, for example, by connector excitations is largely eliminated in advance from the amplitude-modulated carrier signal.

Abstract: A vibration measuring system for the frequency-selective measuring of especially low-frequency vibrations relevant in the area of automation and motive power engineering is disclosed which allows an economical vibration analysis of frequencies in the range of from 0 to 1 kHz. For this purpose, a broad-band transmitting structure which is directly induced by the excitation signal to be determined is coupled to a receiving structure by an electrostatic or inductive force. This force coupling brings about an amplitude modulation of a carrier signal inducing the receiving structure. The spectrum of the amplitude-modulated carrier signal can then be used to extract the actual excitation signal, e.g. by suitably choosing the frequency of the carrier signal.

Abstract: It is an object of the present invention to provide a piezoelectric sensor sensing a substance to be measured in a sample solution, thereby conducting high-precision measurement. As a concrete solving means, a piezoelectric sensor is structured such that it includes a pressing member in which a solution storage space having a bottom surface being one surface of a piezoelectric resonator provided to cover a recessed portion of a wiring board is formed, which includes an annular projection provided to surround the solution storage space and pressing a portion, of the one surface of the piezoelectric resonator, outside the recessed portion toward the wiring board to fix a position of the piezoelectric resonator, and which is made of an elastic material, and the annular projection is structured such that both side surfaces thereof get smaller in diameter toward a lower side and a distance between the both side surfaces gets smaller toward the lower side.

Abstract: The present invention is a mechanical oscillator for detection and measurement of corrosive foreign materials. The elements include a mechanical oscillator that is mechanically excited, wherein the mechanical oscillator has a resonant frequency, f, and a quality factor, Q. A fuse fixed to the oscillator to change oscillator amplitude to and from essentially zero to resonance amplitude. In a preferred embodiment, the mechanical oscillator has the shape of a tuning fork where one region is compatible with the service fluid and the other region is incompatible with the service fluid or other contaminant. The sensor alarms when a measured amount of the incompatible material has been removed or the physical strength of the material has been compromised.

Abstract: A vibration sensor for detecting a vibration of a vibrating object includes a plurality of detecting members. Each of the detecting members includes a vibrating portion disposed to be separated from the vibrating object, a transmitting portion for transmitting the vibration from the vibrating object to the vibrating portion, and a detecting portion disposed on a vibrating face of the vibration portion. The detecting portion outputs an electrical signal corresponding to a resonance of the vibrating portion. At least two of the vibrating portions of the detecting members have resonance frequencies, which are different from each other.

Abstract: A vibratory sensor includes a resonator element including (i) a first base portion and a second base portion, each of the first and the second base portions having an upper main surface and a lower main surface, (ii) a resonating arm extended in a beam shape between the first and the second base portions to be vibrated at a predetermined resonance frequency, (iii) a first narrow portion formed by reducing a width of a portion extended from the first base portion to be smaller than a width of the first base portion in a direction orthogonal to an extending direction of the resonating arm, (iv) a second narrow portion formed by reducing a width of a portion extended from the second base portion to be smaller than a width of the second base portion in the direction orthogonal to the extending direction of the resonating arm, (v) a first support portion extended from the first narrow portion in a direction opposite to the first base portion, and (vi) a second support portion extended from the second narrow portio

Abstract: It is an object of the invention to provide an agitation method for sufficiently agitating a mixture of a solution such as a buffer solution and a material to be detected, with no need of any dedicated unit for agitation, for measurements using a quartz crystal oscillator. The method for agitating a liquefied material using a quartz crystal oscillator in vibrating the quartz crystal oscillator at a given frequency and measuring the variation of the frequency due to a substance in contact with the quartz crystal oscillator, is that the quartz crystal oscillator is vibrated at other frequency different from the given frequency and equal to or higher than the fundamental vibration frequency to agitate a liquid containing the substance.

Abstract: According to embodiments of the present invention, vibration sensor array includes at least two microelectromechanical systems (MEMS) vibration sensors formed on a substrate. The vibration element of the first vibration sensor is a different type than the vibration element of the second vibration sensor. For example, the at least two different vibration elements may be selected from a cantilever beam, a bridge beam, a membrane, and/or an annular diaphragm.

Abstract: An apparatus comprising a substrate and an array of vibration sensors formed on the substrate, the array comprising two or more vibration sensors, wherein each vibration sensor in the array has a different noise floor and a different operational frequency range than any of the other vibration sensors in the array. A process comprising forming an array of vibration sensors on a substrate, the array comprising two or more vibration sensors, wherein each of the two or more vibration sensors in the array has a different noise floor and a different operational frequency range than any of the other vibration sensors in the array. Other embodiments are disclosed and claimed.

Abstract: A specific failure occurring during operation of a technical installation is detected by acquiring an acoustic and/or optical signal emitted by a device assigned to at least one component of the technical installation whereby the device is being activated mechanically.

Abstract: The drop impact measuring system has i) a plurality of bimorph-type acceleration sensor containing a plurality of free vibrating sections each of which has individual draw-out electrodes; ii) a switch section for selecting output from the bimorph-type acceleration sensors; iii) an amplifying circuit for amplifying a signal applied via the switch section from the acceleration sensors; and iv) a logic circuit for logically evaluating the output from the amplifying circuit and controlling the switch section according to the result acquired from the logical evaluation.

Abstract: A directionally-sensitive device for detecting and processing vibration waves includes an array of polymeric optical waveguide resonators positioned between a light source, such as an LED array, and a light detector, such as a photodiode array. The resonators which are preferably oriented substantially perpendicularly with respect to incoming vibration waves, vibrate when a wave is detected, thus modulating light signals that are transmitted between the light source and the light detector. The light detector converts the modulated light into electrical signals which, in a preferred embodiment, are used to drive either the speaker of a hearing aid or the electrode array of a cochlear implant. The device is manufactured using a combination of traditional semiconductor processes and polymer microfabrication techniques.

Abstract: A receiver of an ultrasonic sensor includes reception elements, each of which has a shape of a flat rectangular plate. The reception elements are arranged one-dimensionally on a plane so that the reception surfaces face the same direction and that the reception elements are aligned with small intervals in the width direction thereof while longitudinal ends of the reception elements at a certain side are aligned in a straight line. The widths and the thicknesses of the reception elements are even, while the longitudes of the reception elements are uneven. The both longitudinal ends of the reception elements are fixed to prohibit the vibration of the ends. The longitudes are designed so that the primary resonance frequencies of the reception elements are uneven.

Abstract: A vibrator for generating a signal for measuring a physical quantity using a vibrator is provided, including at least one bending vibration arm vibrating in bending mode along a specified plane and having a first end, an opposed second end, and first and second main faces that are substantially parallel with each other. A base portion is provided at the first provided at the first end of the bending vibration arm, a weight portion is provided at the second end of the bending vibration arm, and grooves are formed on the first and second main faces. The vibrator further includes driving means for exciting a driving vibration in the vibrator, and detecting means provided on one of the bending vibration arms for detecting an output signal based on detection vibrations induced in the vibrator responsive to the physical quantity to be measured.

Abstract: A sensor for detecting acoustic energy includes a microstructure tuned to a predetermined acoustic frequency and a device for detecting movement of the microstructure. A display device is operatively linked to the movement detecting device. When acoustic energy strikes the acoustic sensor, acoustic energy having a predetermined frequency moves the microstructure, where the movement is detected by the movement detecting device.

Abstract: The present invention provides a configuration where all optical parts of a monitoring system are contained within a seal and within the generator itself. Non-optical preamplifier functions may also be placed within the seal. In this configuration there is an electrical rather than optical feed-through at the generator wall, which is hermetically sealed, unlike a fiber optic feed-through. The fiber optic light source and detector for each sensor is located in the seal on the generator side of the hermetic electrical feed-through. Electrical power and the sensor's converted electrical vibration signals pass through the electrical feed-through to preamplifier circuitry on the outside of the seal where direct electrical connection is then made to a main chassis unit.

Abstract: A stylus structure (40) integrally incorporating a stylus (2), a vibrator (4), a detector (6), a first secondary magnetic circuit (12) and a second primary magnetic circuit (21), and a stylus support (30) integrally incorporating a first primary magnetic circuit (11) and a second secondary magnetic circuit (22) are mutually fittable, thereby achieving signal transmission by the respective magnetic circuits using no electrical contact.

Abstract: A device (10) for receiving date transmitted as impulses through an input transmission body (16) is provided. The device (10) has a vibration sensitive transducer (50) which constitutes part of a floating mass assembly (40) with a pick-up portion (42). The pick-up portion (42) is biased towards a surface of a rigid body that is either the input transmission body (16) or a vibrations transmissive member (151). The assembly (40) has a freedom of movement permitting it to vibrate independently from the rigid body.

Abstract: A method for selecting trees for harvest according to a predetermined criterion is provided which includes at least the steps of applying a vibrative member to the tree, vibrating the vibrative member, determining the resonance properties of the vibrative member, calculating an observed quality factor associated with the vibrative member vibrations, and, comparing the observed quality factor with a predetermined relationship between the quality factor and the tree selection criterion. A portable tree probe, suitable for field use, is also provided.

Abstract: A monitoring system with a power supply built therein, which is capable of setting installation expenses at low cost and obtaining a stable result of monitoring for a predetermined period. The monitoring system comprises a sensor unit having sensors and a power supply incorporated therein, and a portable data logger having a communication module and a power supply built therein. Physical quantities such as vibrations, temperatures, and pressure, of an object to be monitored are detected by the sensors, followed by transmission to the portable data logger, whereby the state of operation of the object is displayed.

Abstract: A liquid-quantity monitoring apparatus includes: a piezoelectric device having a vibrating part capable of being exposed at least partly to a liquid-containing space, the piezoelectric device being capable of vibrating the vibrating part by a given drive signal and of generating a signal representing back electromotive force generated by vibration of the vibrating part; and a liquid-quantity determining unit for determining a quantity of liquid remaining in the liquid-containing space, to which the vibrating part is exposed, based on a resonance frequency of a residual vibration signal output from the piezoelectric device due to a residual vibration of the vibrating part after the vibrating part has been vibrated by the drive signal.

Abstract: A sensor for detecting acoustic energy includes a microstructure tuned to a predetermined acoustic frequency and a device for detecting movement of the microstructure. A display device is operatively linked to the movement detecting device. When acoustic energy strikes the acoustic sensor, acoustic energy having a predetermined frequency moves the microstructure, where the movement is detected by the movement detecting device.

Abstract: An ultrasound radiating and receiving device comprises a piezoelectric substrate, an interdigital arrangement of first and second comb-shaped electrodes, and a counter electrode. The interdigital arrangement is mounted on an upper end surface of the piezoelectric substrate. The counter electrode is formed on a lower end surface of the piezoelectric substrate, and is in contact with a surface-part of a material through the lower end surface of the counter electrode. When an input electric signal is applied between the first comb-shaped electrode and the counter electrode, a longitudinal wave is radiated into the material through the surface-part of the material along the direction vertical to the lower end surface of the piezoelectric substrate. If the longitudinal wave is reflected at an object located inside the material, a reflected longitudinal wave is detected between the second comb-shaped electrode and the counter electrode as a delayed electric signal.

Abstract: An ultrasound radiating and receiving device comprises a piezoelectric substrate, an interdigital arrangement of first and second comb-shaped electrodes, and a counter electrode. The interdigital arrangement is mounted on an upper end surface of the piezoelectric substrate. The counter electrode is formed on a lower end surface of the piezoelectric substrate, and is in contact with a surface-part of a material through the lower end surface of the counter electrode. When an input electric signal is applied between the first comb-shaped electrode and the counter electrode, a longitudinal wave is radiated into the material through the surface-part of the material along the direction vertical to the lower end surface of the piezoelectric substrate. If the longitudinal wave is reflected at an object located inside the material, a reflected longitudinal wave is detected between the second comb-shaped electrode and the counter electrode as a delayed electric signal.

Abstract: This invention is pertaining to multi purpose shock sensor comprising three conductive plates arranged in 3 layers in parallel which make 2 variable capacitors connected in series. Two outer plates are firmly attached to a supporting insulating material and the center plate is located between the 2 outer plates and arranged as movable by resilient element toward either side of the outer plate depending on the direction of the impact felt on the shock sensor causing changes of the capacitance values of the both capacitors. If the 2 capacitors are connected across a voltage source through a resistor, the voltage is charged across the 2 capacitors and their charged values are inversely proportional to their capacitance values. Moving the center plate due to a shock causes changes on both capacitance values, which change voltages across the capacitors, and the changed voltage can be used to activate an object.

Abstract: A sensor for an electrostatic detector including an elongated vibratory element supported at a mechanical node at one end in the manner of a cantilever beam, a sensitive electrode on the vibratory element near the other end and adapted to be disposed toward an electrical charge, field or potential being measured, and a driver transducer on the vibratory element for vibrating the element in a direction to vary the capacitive coupling between the electrode and the electrical charge, field or potential being measured. An amplifier and the sensitive electrode are combined in an assembly on the vibratory element thereby providing a low impedance amplifier output which in turn allows a narrow spacing around the vibratory element to prevent entry of contaminants. The vibratory element can be provided with a structure which allows measurements with various spatial resolution characteristics.

Abstract: A method and/or an apparatus for determining the dynamic response of a microstructure is disclosed. A piezocomposite ultrasonic transducer device formed of a piezoelectric material and a polymer material around said piezoelectric ceramic material is used to provide a pulsed bulk acoustic wave having a bandwidth of at least 20% to excite a microstructure. The microstructure is attached onto the transducer, and the pulsed bulk acoustic wave generated through the transducer in response to a pulse voltage excites the microstructure to vibrate. Meanwhile, the dynamic response of the microstructure can be monitored by a laser Doppler vibrometer, and shown by an oscilloscope.

Abstract: A sensor for an electrostatic detector including an elongated vibratory element supported at a mechanical node at one end in the manner of a cantilever beam, a sensitive electrode on the vibratory element near the other end and adapted to be disposed toward an electrical charge, field or potential being measured, and a driver transducer on the vibratory element for vibrating the element in a direction to vary the capacitive coupling between the electrode and the electrical charge, field or potential being measured. The driver transducer is at a location along the beam and is operated at a vibratory frequency such that a virtual mechanical node appears along the beam. This, in turn, reduces vibration at the mechanical attachment node so that the degree of stiffness of the mechanical node does not affect the operating frequency and/or the displacement at the free end of the cantilever.

Abstract: Disclosed is an evaluation method of a golf club, where a rear end portion of a club shaft is vibrated in a state where a tip portion of the club shaft is fastened to measure a frequency per unit time, and a golf club using the club shaft is evaluated based on the frequency.

Abstract: An apparatus and a method for determining a vibrational characteristic of a golf club shaft. The apparatus includes a table having a clamping structure for clamping the golf club shaft thereto. A multi-dimensional accelerometer is coupled to a tip end of the golf club shaft. The multi-dimensional accelerometer is also coupled to a computer. When the golf club shaft is vibrated, the multi-dimensional accelerometer converts the vibrational signal into an electrical signal which is transmitted to the computer. The computer conditions the electrical signal and outputs a signal indicative of the frequency of vibration of the golf club shaft. The stiffness of the golf club shaft is determined from the vibrational frequency of the golf club shaft.

Abstract: The cantilever of a probe-based metrology instrument such as an AFM is deflected by directing a beam of ultrasonic energy at the cantilever to apply ultrasonically generated acoustic radiation pressure to the cantilever. The energy is generated by an ultrasonic actuator such as a ZnO transducer driven by a power source such an RF signal generator. The transmitted beam preferably is shaped by focusing, collimation, or the like so that it impinges at least primarily on a region of interest of the cantilever such as the free end. The ultrasonic actuator produces a much better controlled force on the cantilever than can be achieved through the use of a traditional piezoelectric actuator and, accordingly, produces a response free of spurious effects (at least when the cantilever is operating in liquid). It also has a frequency bandwidth in the MHz range.

Abstract: A stylus 20 is mounted directly on detector 32 and the detector 32 is mounted directly on a holder 10. Thus, an vibration-type contact detection sensor 1 is formed in a state in which the holder 10 and the stylus 20 are placed out of contact with each other and the stylus 20 and the detector 32 are placed in contact with each other. Therefore, attenuation of vibration and status change of the stylus 20 by the holder 10 can be circumvented and vibration and status change of the stylus 20 can be propagated directly to the detector 32, so that the detector 32 can detect vibration and status change of the stylus 20 with high sensitivity, and contact with a workpiece can be detected with high sensitivity.

Abstract: In order to achieve reproducible vibration excitation of a quartz crystal even under the technical conditions which prevail when it is used for monitoring electroplating baths, a mounting for the quartz crystal 7 is proposed. The mounting for the quartz crystal 7 has two holding elements 3, 6, 14 detachably connected to one another as a form-fit, and at least two contact elements 5, 9 on the holding elements 3, 6, 14 brought into electrical contact with the contacting surfaces 32 of the quartz crystal 7. The quartz crystal 7 is fitted with the holding elements 3, 6, 14 and/or the contact elements 5, 9 at least one of the contact elements 9 being configured as a resilient body. The at least one resilient contact element 9 has an end face 34, 134 for electrically contacting the quartz crystal 7, the size of which face corresponds roughly to the size of the quartz crystal 7.

Abstract: A liquid-quantity monitoring apparatus includes: a piezoelectric device having a vibrating part capable of being exposed at least partly to a liquid-containing space, the piezoelectric device being capable of vibrating the vibrating part by a given drive signal and of generating a signal representing back electromotive force generated by vibration of the vibrating part; and a liquid-quantity determining unit for determining a quantity of liquid remaining in the liquid-containing space, to which the vibrating part is exposed, based on a resonance frequency of a residual vibration signal output from the piezoelectric device due to a residual vibration of the vibrating part after the vibrating part has been vibrated by the drive signal.

Abstract: A vibration detecting apparatus includes a bobbin having a moving path of desired length in an inner periphery of the bobbin; a core movable along the moving path in the inner periphery of the bobbin by vibration applied from exterior or vibration applied to the bobbin; and a coil wound on an outer periphery of the bobbin, the inductance of which being changed in accordance with the shift of the core.

Abstract: A suspended micromachined structure including a proof mass and multiple support arms configured to suspend the mass above a substrate. At least one support arm may include two spring elements, each attached to the substrate as well as to a rigid lateral element. Thus, there may be three points of attachment along each lateral element. These points of attachment create three effective flexure points along each rigid lateral element that allow the proof mass to move with a great deal of freedom axially, parallel to the substrate. The linearity of the spring constant that acts on the proof mass may be improved.

Abstract: A step counting device includes a top casing, a bottom casing, a display, and two operating buttons. A circuit board is arranged in the space between the top casing and the bottom casing. An open area is formed on the edge of the circuit board and a ceramic vibration detecting mechanism is arranged on the circuit board. One end of the ceramic vibration detecting mechanism is a fixed point located on a fixed position and the other end is a cantilever point extended to the open area of the circuit board and a heavy mass is attached to the cantilever point. The step counting device is attached on a shoe, and the step counting device will be vibrated while a user wears the shoes walking or running. The ceramic vibration detecting mechanism will receive the vibration and a tiny voltage change will be produced to become an input signal to the control circuit on the circuit board.

Abstract: A device for ultrasound radiation into a material comprises a piezoelectric substrate, a first input interdigital transducer, a second input interdigital transducer, an output interdigital transducer, an amplifier, and a voltage controller. All the interdigital transducers are formed on one end surface of the piezoelectric substrate. If an input electric signal is applied to the first input interdigital transducer, a first elastic wave is excited in the piezoelectric substrate. A non-leaky component of the first elastic wave is transmitted to the output interdigital transducer, and detected at the output interdigital transducer as a delayed electric signal, which is amplified via the amplifier. A signal part of an amplified electric signal is fed back to the first input interdigital transducer, again.

Abstract: Vibration transducer unit for converting vibrations to electric signals, in which unit there is a transducer part (11) and a signal processing part (14), like a preamplifier part. The transducer part (11) and the signal processing part (14) are integrated to a single structure.

Abstract: A bistable sensor with a tunable threshold for use in microelectromechanical systems. The sensor uses electrostatic force to modify the threshold and to disable the sensor in a deflected position once a sustained extreme in vibration is detected. Potential applications include mechanical implementations of signature analysis to automatically eliminate large amplitude noise at a specific frequency, shock detection without requiring quiescent DC power consumption, and determination of the magnitude of a shock.

Abstract: A warning system to alert the driver of a vehicle that a tire or wheel on the vehicle has become loose or a tire tread is separating from a tire core is disclosed. The warning system comprises a first metallic member mounted to the vehicle, a second metallic member mounted adjacent the surface of the tire being monitored and in a spaced-apart relationship with respect to the first member and an insulating member interposed between the first and second members forming a normally open electrical contact between the first and second members. When a tire or wheel becomes loose on the vehicle or a tire tread starts separating from its tire core, the surface of the tire contacts the second member causing it to move laterally and contact the first member resulting in the closing of the normally open electrical contact between the first and second members causing an audible and visual alarm to be actuated alerting the driver of the vehicle of a dangerous condition.

Abstract: The present invention provides a method and apparatus for recording vehicle motion. The self-contained vehicle motion recorder apparatus is a sealed unit that contains at least a power source, and controller, sensor and recording devices. The controller device includes a power consumption manager that manages and conserves the overall power consumption of the apparatus. A sensor device is further included in operable communication with the controller device that produces signals that represent the vehicle's motion as a function of time. Additionally, a recording element is provided in operable communication with the controller for storing data that corresponds to the signals. A communication interface is further provided such that data may be read from the apparatus and commands and data may be written into the apparatus, from an external device.