Abstract: A rangefinder apparatus includes an infrared emitting device (IRED) for projecting a light beam toward a target object; a position sensitive detector (PSD) for detecting light of the light beam reflected from the target object and outputting an output signal corresponding to a distance to the target object; an output circuit for charging an integrating capacitor according to the output signal of the PSD and an analog-to-digital (A/D) converter for converting a voltage of the integrating capacitor after an end of a rangefinding operation including a number of light-projecting actions by the IRED, light-detecting actions by the PSD, and integrating actions by the output circuit are repeated. Multiple rangefinding operations are carried out with a different number of repetitions, and the distance is determined according to respective values obtained by A/D conversions after the rangefinding operations. Consequently, conversion errors in A/D conversions are reduced, whereby the rangefinding accuracy is improved.

Abstract: A method of determining a range of an object includes emitting light toward a target and sensing light reflected by the target. Signals corresponding to the sensed light are integrated during multiple integration periods. Each integration period is different from other integration periods. A range of the target can be calculated based on the integrated signals. A range finder for performing the foregoing technique also is disclosed.

Abstract: In an object detecting system, a first discriminating unit discriminates an object which has a reflected wave having a reception level calculated by a reception level calculating unit, equal to or larger than a first reference level. A second discriminating unit discriminates an object, the distance to which, calculated by a distance calculated unit, is equal to the distance to the object discriminated by the first discriminating unit, and which has a reflected wave whose reception level calculated by the reception level calculating unit is equal to or smaller than a second reference level. A virtual image determining unit determines the object discriminated by the second discriminating unit as a virtual image of the actual existing object discriminated by the first discriminating unit. A virtual image deleting unit deletes the virtual image from the result of the recognition provided by an object recognizing unit, whereby only the actual existing object including no virtual image can be detected correctly.

Abstract: An optical transmitter for use in position location or position measurement systems includes (i) an assembly including two optical sources that generate two optical beams which diverge in known ways in a first and second plane, respectively, and are narrow in the orthogonal planes, (ii) a power source which provides power to the assembly to rotate it at a constant angular velocity or with a previously known pattern of velocities through each complete rotation of the assembly, and (iii) a signaling unit that emits a synchronization signal at a specific rotational position of the assembly. The optical transmitter can be used in systems for determining points, lines, planes, distances, areas, volumes, azimuth, elevation, range, angles, or any other positional or spatial variable. The optical transmitter has wide application in, for example, surveying, construction, and the creation of virtual or real environments.

Abstract: In order to control the perpendicularity of a component (10) such as a nuclear fuel pellet, this component is placed upon a support plane and measurements are taken, by means of two pairs of laser micrometers (A1, A2; B1, B2), of the distances separating diametrically opposed generators of the component from a rod of reference (T, T′), at two different levels and in two measuring planes (P, P′) perpendicular to each other. From this is derived a maximum out-of-true perpendicularity of the component being controlled.

Abstract: A photodetecting system for an automatic surveying instrument equipped with an automatic tracking system is capable of controlling the automatic surveying instrument by simple photodetecting means. A collimating optical system collimates the surveying instrument with respect to an object, a splitting optical device splits incident light rays received from the collimating optical system into light rays that travel toward first and second photodetecting devices, respectively, a first light condensing device disposed on an optical path between the first photodetecting device and the splitting optical device gathers the light rays in a first direction, and a second light condensing device disposed on an optical path between the second photodetecting device and the splitting optical device gathers the light rays in a second direction perpendicular to the first direction.

Abstract: A highly precise range measurement instrument is made possible through the use of a novel and efficient precision timing circuit which makes use of the instruments internal central processing unit crystal oscillator. A multi-point calibration function includes the determination of a “zero” value and a “cal” value through the addition of a known calibrated pulse width thereby providing the origin and scale for determining distance with the constant linear discharge of capacitor.

Abstract: A computer diary archives a diary entry by creating, time stamping, authenticating and permanently storing a reference data block along with each diary entry. An archived diary entry can only be modified by placing original text within compartment codes, such as cross-out or tear-out codes, and by placing inserted text within insertion codes so that the original diary entry can be recreated from the modified diary entry. The reference data block, which can be the original diary entry, a canonical version of the original diary entry, or a one way fixed length encryption (hash) of the original diary entry, cannot be modified and is used to authenticate the original diary entry. The diary program also monitors text entry for aliases and relative date phrases, and upon detection, prompts the user for entry or enters a specific identifier for each detected alias in an alias compartment or an absolute date for each relative date phrase in an implied date compartment in the diary entry.

Abstract: A traffic LIDAR device is presented with an increased laser power output in compliance with the IEC 825 standard for class one-type laser systems. Increased laser emitter power output is accomplished by reshaping the emitter source output using an optical fiber which has an inside diameter greater than the minimum dimension of the emitter source. The resulting increased cross-section of the output pulse overcomes the power output limitation that would otherwise be dictated by the emitter minimum dimension.

Abstract: Measuring method and device providing a traveling path of light beam. The traveling path includes a front portion between a target and a prism unit, a refraction portion entering the prism unit and extending inside the prism unit and a first and a second rear portions positioned outside the prism unit and corresponding to the front portion. A visible light beam and an invisible light beam at the same time travel along the front portion. The visible light beam comes from the surface of the target while the invisible light beam is a laser beam coming from a laser transmitter. The laser beam travels along the same path as the visible light beam to reach the surface of the target. Therefore, very long parts of the traveling paths of the visible light beam and the invisible light beam coincide with each other and are commonly directed to a specific portion of the target.

Abstract: A device for detecting optical position, comprising a photodetection unit 40 having a photodetection optical axis 37 and for outputting a photodetection signal corresponding to a light receiving position of a projected light beam, and a modulation grid 42 arranged on said photodetection optical axis and for equalizing distribution of light quantity of a received light beam, wherein a position of the light beam projected on the photodetection unit is detected based on said photodetection signal.

Abstract: The integrated laser and satellite positional system receiver is disclosed. The integrated laser and satellite positioning system receiver can provide a plurality of mobile units with a laser plane data determined with a millimeter relative accuracy. The integrated laser and differential satellite positioning system receiver can also generate and transmit the differential correctional data to a plurality of mobile units. Each mobile unit equipped with a mobile satellite positioning system receiver can use the differential correction data and the high precision laser plane data to improve its position determination capabilities.

Abstract: An optical communication system which includes a transmission path through which a light is transmitted to a specific point, such as to a receiver. The transmission path includes a plurality of sections so that the light travels through the sections to the specific point. Each section overcompensates for dispersion produced in the respective section for the light so that an amount of dispersion for the light at the specific point is substantially zero.

Abstract: In a method, the light beams of two separated optical radar units (each of which are capable of emitting light pulses in a direction and receiving light pulses from the same direction) are directed to a point. The first optical radar unit emits a light pulse to the point and the second optical radar unit detects the light pulse reflected from the object at the point. After a time interval, the second optical radar unit emits a light pulse to the point and the first optical radar unit detects the light pulse reflected from the object at the point. If there is an object at the point, the time difference of the two detected signals from the two optical radar units is the switching time interval. By comparing the two detected signals from the two optical radar units, one can determine whether an object is at the point.

Abstract: An autofocusing apparatus of a telescope for automatically focusing on an object viewed within a field of view of the telescope through a distance-measuring zone arranged in the field of view, includes: a multi-point distance measuring device which divides the distance-measuring zone into at least three distance-measuring zones to detect an object distance on each of the distance-measuring zones; a lens driver which drives a focusing lens group of the telescope along an optical axis thereof; and a controller which controls the lens driver wherein the focusing lens group is moved to perform an autofocusing operation in accordance with a result of the each object distance detected by the multi-point distance measuring zones. The controller compares the each object distance detected by the multi-point distance measuring device with each other.

Abstract: Apparatus for providing simultaneous jamming of a number of missiles is disclosed comprising a plurality of reticles each having a pattern therein which provides necessary spin frequency and carrier frequency (if required) for the missile to be jammed. The reticles are arranged in series and modulate a source of radiation and generate the spin and carrier frequencies by blocking or rejecting radiation within the spectral passband of the missile to be jammed.

Abstract: A method for determining the relative motion of a surface with respect to a measurement device comprising: illuminating the surface with incident illumination; detecting illumination reflected from the surface to form at least one detected signal; and determining the amount of relative motion parallel to the surface from said at least one detected signal, characterized in that said determining includes correcting for the effects of relative motion perpendicular to the surface.

Abstract: An optical installation for determining the relative positions of at least two objects, such as vehicle wheels, includes two optical systems for determining the position of an object in space, each with respect to its observation frame. An optical reference system includes a target visible from the other optical system in the absence of the objects. The other optical system includes a device for analyzing an image of the target and a device for positioning the target with respect to its observation frame, so as to deduce therefrom the position of the observation frame of the other optical system with respect to the observation frame of the of the optical reference system, on the basis of the positions of the target with respect to the observation frame and of the target with respect to the observation frame of the optical reference system.

Abstract: A system for detecting deviations from an optical axis of one or more individual component beams associated with plural laser beams. The system includes a first mechanism that selectively isolates individual component beams from plural laser beams and provides the individual component beams as output in response thereto. A second mechanism detects deviations from a desired optical axis of the individual component beams output from the first mechanism. In the specific embodiment, the system further includes a mechanism that automatically corrects the detected deviations of each component beam of the plural beams. A beam pick-off device, such as a pick-off collimating lens or beam splitter, redirects a sample of the plural beams, which represents separated plural beams to a color wheel. The individual component beams include red, green, and blue laser beams.

Abstract: When the reflectance of an object at a distance to be measured is low and when the distance to the object is far, these conditions are discriminated and the distance is measured with a clamp signal set at a low level, thereby enhancing distance measurement accuracy. First a distance measurement is carried out with the clamp signal set at a high level. When the first distance value is larger than a predetermined distance, a second distance measurement is carried out with the clamp signal set at the low level. Then it is determined whether the second distance value is larger than a set value. When the second distance value is larger than the set value, the clamp signal is set to the high level and third a distance measurement is carried out. When the second distance value is not larger than the set value, on the other hand, the clamp signal is set to the low level under certain conditions and the third distance measurement is carried out.