An optical displacement sensing system is provided. With configuration of an optical sensor disposed on a displacement platform and in cooperation with a broadband light source and an optical spectrum analyzer, when the displacement platform moves, the waveguide grating of the optical sensor is resonated and the reflected light provided with a resonance wavelength is formed. The waveguide grating has the plurality of grating periods, and when the displacement platform moves to a different position to make the broadband light source correspond to a different grating period, the position can correspond to the different resonance wavelength. Therefore, according to the aforementioned configuration, the position is determined according to the different resonance wavelength, instead of using an optical encoder; furthermore, the micrometer-scale or nanometer-scale displacement detection is achieved.

A distributed pressure, temperature, strain (DPTS) sensing cable includes at least two slotted fiber optic metal wires each having a slot groove extended along in an outer circumference of the wires to encapsulate optical fibers in the slot grooves. The two slotted fiber optic metal wires have characteristics different from each other.

The present invention relates to a method of fabricating a nanowire connected to an optical fiber, the method comprising the steps of: a) filling a micropipette with a material solution to form a nanowire; b) coaxially aligning the micropipette with the optical fiber at one end of the optical fiber such that a longitudinal axis of the optical fiber and a longitudinal axis of the micropipette are aligned in a line; c) forming a meniscus of the material solution to form the nanowire in the coaxially aligned state; and d) fabricating the nanowire by evaporating a solvent from the material solution to form the nanowire while lifting the micropipette in a state in which the meniscus is formed, in a direction away from the optical fiber. The method further comprises a step of a step of controlling a shape of the distal end of the nanowire by irradiating a laser to the nanowire fabricated.

To provide a confocal displacement sensor capable of easily and accurately measuring displacement of a measurement object. Light having a chromatic aberration is converged by a lens unit 220 and irradiated on a measurement object S from a measurement head 200. Light having a wavelength reflected while focusing on the surface of the measurement object S passes through the optical fiber 314 in the measurement head 200. The light passed through the optical fiber 314 is guided to a spectral section 130 in a processing device 100 and spectrally dispersed. In the processing device 100, the light spectrally dispersed by the spectral section 130 is received by a light receiving section 140. A light reception signal output from the light receiving section 140 is acquired by a control section 152. The control section 152 measures displacement on the basis of the acquired light reception signal and gives the light reception signal to a PC 600 on the outside. A CPU 601 of the PC 600 causes a display section 700 to display, as change information, a change from a light reception signal acquired at a point in time before a present point in time to a light reception signal acquired at the present point in time.

Provided are optical-sensing demodulation module and optical-sensing system. Optical-sensing demodulation module includes: package housing, functional circuit, optical receiving assembly, and optical transmitting assembly. The first side surface of the package housing is provided with first fiber optic interface and second fiber optic interface. The second side surface is provided with an electrical interface. The functional circuit is connected with the electrical interface. The optical receiving assembly is connected with the first fiber optic interface and the functional circuit. The optical transmitting assembly is connected with the second fiber optic interface and the functional circuit. The functional circuit is provided near the first side surface. The optical receiving assembly and optical transmitting assembly are both provided near the second side surface. The optical receiving assembly and the optical transmitting assembly are provided at intervals along direction in which the first fiber optic interface points to the second fiber optic interface.

Provided is a sensor head capable of reduction in size while securing measurement accuracy. A sensor head includes a first case section and a second case section each having a substantially cylindrical shape and an end portion of which is open, and a third case section configured to connect the first case section and the second case section, a diffraction lens is disposed in the first case section, an objective lens is disposed in the second case section, and a mirror member is disposed in the third case section and configured to bend light entering the diffraction lens side toward the objective lens side.

A method of improving measurement speed of distributed optical fiber sensors by adopting orthogonal signals and the system thereof is disclosed, which is related to the optical fiber sensor field and solves the problems that conventional technology will increasing the bandwidth of the received signal, reducing the signal-to-noise ratio of the received signal or distortion the spatial resolution of the system. The method comprises steps of generating N periodic orthogonal optical pulse sequence; injecting the N periodic orthogonal optical pulse sequence into the optical fiber under test(5); collecting the scattered light signal; demodulating the scattered light signal with the local oscillating light and then converting into digital signals; extracting the scatter information of the orthogonal optical pulses from the collected digital signals; and arranging the scattered information in order of precedence of the infusion. The measurement speed of the distributed optical fiber sensors is improved by N1 times.

Fiber-optic equipment is often deployed in various locations, and performance of fiber-optic transmissions may be monitored as a gauge of equipment status to prevent costly and inconvenient communication outages. Events that damage equipment that eventually result in outage and may be desirable to address proactively, but the occurrence of such events may be difficult to detect only through equipment performance. Presented herein are techniques for monitoring and maintaining fiber-optic equipment performance via enclosure sensors that measure physical properties within a fiber-optic equipment enclosure, such as temperature, pressure, light, motion, vibration, and moisture, which are often diagnostic and predictive of causes of eventual communication outages, such as temperature-induced cable loss (TICL), incomplete flash-testing during installation, exposure to hazardous environmental conditions, and tampering. An enclosure sensor package transmits the physical measurements to a monitoring station, and automatic determination of enclosure-related events may enable triaging and transmission of repair alerts to maintenance personnel.

A system for monitoring a condition of a pan line associated with a longwall mining system includes multiple pan segments arranged in a successive manner. Adjacently located pan segments are moveably coupled by an interconnecting joint. An underside of each pan segment defines an opening whose axis is parallel to a plane of the associated pan segment. The system also includes a fiber optic shape sensing system that has a fiber optic cable disposed along the multiple pan segments and located within the opening of each pan segment. A controller coupled to the fiber optic cable detects a shape of the fiber optic cable, identifies a position of each pan segment based on the detected shape of the fiber optic cable, and determines if a fault exists in the interconnecting joints between adjacently located pan segments based on the identified positions of respective ones of the adjacently located pan segments.

The invention relates to fibre optic vibration and acceleration sensors comprising a dielectric mirror and a first light-guiding fibre connected to a coupler, the coupler being further connected via second light-guiding fibres to a light source and a detector that generates a voltage from incident light.

Said sensors are characterised in particular by their simple implementation.

For this purpose, a free end region of the first fibre is spaced apart from the dielectric mirror such that an edge of the dielectric mirror is located in the emergent light of the first fibre. In the unexcited state, the voltage of the detector generated from the light incident on the end of the first fibre is smaller than the voltage generated by the detector when the aperture cone of the first fibre is completely covered by the dielectric mirror and there is thus maximum reflection. Said voltage is a measure of the fibre optic vibration and acceleration sensor.

A fibre is itself therefore used as a vibration-sensitive element.